CN111644895A - Water tank device for separating iron chips and precipitates in waste liquid in numerical control processing - Google Patents

Abstract

The invention discloses a water tank device for separating iron filings and precipitates in waste liquid in numerical control processing, which comprises a water tank body, wherein a cutting oil channel is arranged in the water tank body, a push groove is formed in the left side of the upper end of the cutting oil channel, a push device is arranged in the push groove and comprises a push block in sliding fit with the push groove, a filter screen is arranged in the cutting oil channel, the push block can push the cutting oil precipitates and the iron filings filtered by the cutting oil channel out, the right side of the cutting oil channel is communicated with a separation cavity, a separation device is arranged in the separation cavity and comprises a rotating shaft in rotating fit with the left wall of the separation cavity, a magnetic thread groove is formed in the left side of the rotating shaft, and a non-magnetic groove communicated with the magnetic thread groove is formed in the right side of the rotating cylinder.

Description

Water tank device for separating iron chips and precipitates in waste liquid in numerical control processing

Technical Field

The invention relates to the technical field of numerical control processing, in particular to a water tank device for separating scrap iron and precipitates in waste liquid in numerical control processing.

Background

With the development of science and technology, more and more manufacturers of numerical control machining use, in daily machining, because cutters and cutting materials can generate a large amount of heat for cutting, cutting oil is often used for assisting cutting, a water tank is often installed below a numerical control machine tool to achieve the purpose of cutting oil circulation, but in production, cutting scrap iron is often brought into the water tank by the cutting oil, the cutting oil is oxidized to generate precipitates, the precipitates are not only smelly, but also the working efficiency of the cutting oil is greatly reduced, and the scrap iron also has great use, so that the invention discloses a water tank device capable of filtering the precipitates and collecting and compressing the scrap iron is very important.

Disclosure of Invention

The invention aims to provide a water tank device for separating iron chips and precipitates in waste liquid in numerical control processing, which is used for overcoming the defects in the prior art.

The water tank device for separating the iron filings and the precipitate in the waste liquid in the numerical control processing comprises a water tank body, wherein a cutting oil channel is arranged in the water tank body, a push groove is formed in the left side of the upper end of the cutting oil channel, a push device is arranged in the push groove and comprises a push block in sliding fit with the push groove, a filter screen is arranged in the cutting oil channel, the push block can push the cutting oil precipitate and the iron filings filtered by the cutting oil channel out, a separation cavity is communicated with the right side of the cutting oil channel, a separation device is arranged in the separation cavity and comprises a rotating shaft in rotating fit with the left wall of the separation cavity, a magnetic thread groove is arranged on the left side of the rotating shaft, a non-magnetic groove communicated with the magnetic thread groove is arranged on the right side of the rotating cylinder, and after the precipitate is pushed into the separation cavity, take magnetism thread groove can be inhaled iron fillings, the iron fillings groove has been seted up to the disengagement chamber downside, be provided with extrusion device in the iron fillings groove, extrusion device is including being located the iron fillings groove with the spread groove of intercommunication between the disengagement chamber, the left downside of disengagement chamber has been seted up and has been located the left sediment of spread groove is collected the chamber, precipitate and iron fillings after separating, iron fillings will fall into the sediment is collected the chamber and is collected, falls into the iron fillings groove prepares to extrude into the piece.

On the basis of the technical scheme, the pushing device further comprises a rack groove communicated with the left side of the pushing groove, the rack groove is in sliding fit with a sliding rack fixedly connected with the pushing block on the right side, a connecting spring is connected between the sliding rack and the left wall of the rack groove, a bevel gear linkage groove is formed in the lower side of the rack groove, the bottom wall of the bevel gear linkage groove is rotatably connected with a connecting shaft, the connecting shaft is positioned in the rack groove and fixedly connected with a rotating half gear meshed with the sliding rack, the connecting shaft is positioned in the internal spline and connected with a sliding bevel gear, a second annular groove is formed in the sliding bevel gear, a vertical part on one side of an oil path is fixedly arranged on the top wall of the bevel gear linkage groove, a piston moving rod rotationally connected with the second annular groove is in sliding fit in the oil path, a bevel gear meshing, the left wall of the bevel gear meshing groove is matched with a motor shaft in a rotating mode, the motor shaft is located in the bevel gear linkage groove and is fixedly connected with a central bevel gear which can be meshed with the sliding bevel gear, the motor shaft is located in the bevel gear meshing groove and is fixedly connected with a connecting bevel gear, the motor shaft extends to the left end to be connected with a working motor which is embedded in the inner wall in a power mode, the top wall of the left side of the separation cavity is provided with a vertical part of the other side of the oil way, the bottom of the filter screen is fixedly connected with a piston weighing rod which is matched with the oil way in a sliding mode.

On the basis of the technical scheme, the separating device also comprises a transmission groove positioned on the left side of the separating cavity, a torsional spring is connected between the left wall of the separating cavity and the left wall of the rotating cylinder, the rotating shaft is positioned in the transmission groove and is fixedly connected with a transmission gear, the right wall of the transmission groove is rotatably connected with a half-toothed shaft positioned on the lower side of the rotating shaft, the half-toothed shaft is silent, a transmission half-gear meshed with the transmission gear is fixedly connected in the transmission groove, a bevel gear one-way groove is formed on the lower side of a bevel gear linkage groove, the half-toothed shaft extends to the left side of the bevel gear one-way groove and is rotatably connected with a one-way shaft, a matching groove is formed in the one-way shaft, the half-toothed shaft is positioned in the matching groove and is fixedly connected with a matching block, a one-way groove is, the electromagnetic separation device is characterized in that a one-way spring is connected between the one-way block and the top wall of the one-way groove, the one-way shaft is located in a bevel gear one-way groove and fixedly connected with a driving bevel gear, the connecting shaft is located in a bevel gear one-way groove and fixedly connected with a driven bevel gear meshed with the driving bevel gear, the top wall of the separation cavity is fixedly connected with an electrified slide rail, the left side of the electrified slide rail is fixedly connected with a slide rail, the electrified thread groove is connected with a slide pin which is not provided with the magnetic groove and is slidably connected with the electrified slide rail, and the upper side of the.

On the basis of the technical scheme, the extruding device further comprises a bevel gear transmission groove positioned on the lower side of the bevel gear meshing groove, a rotating shaft is arranged between the bevel gear transmission groove and the bevel gear meshing groove, the rotating shaft is fixedly connected with a meshing bevel gear meshed with the connecting bevel gear in the bevel gear meshing groove, the rotating shaft is positioned in the bevel gear transmission groove, a spline is connected with a spline bevel gear in a spline manner, a first ring groove is formed in the spline bevel gear, the top wall of the bevel gear transmission groove is provided with a vertical part on one side of an oil pipe, the right side of the oil pipe is in sliding fit with the first ring groove in a rotating manner, a reciprocating cavity is formed in the lower side of the sediment collection cavity, a transmission shaft is in rotating fit with the wall body between the reciprocating cavity and the bevel gear transmission groove, and the transmission shaft is fixedly linked with a rotating bevel gear capable of being meshed with, the transmission shaft is positioned in the reciprocating cavity and is fixedly connected with a rotary bevel gear, the back wall of the reciprocating cavity is in running fit with an extension shaft, the extension shaft is positioned in the reciprocating cavity and is fixedly connected with a driven bevel gear meshed with the rotary bevel gear, the extension shaft is positioned in the reciprocating cavity and is fixedly connected with a rotating wheel positioned at the front side of the driven bevel gear, the rotating wheel is fixedly connected with a limiting pin, the reciprocating cavity is in sliding connection with a limiting block, the limiting block is provided with a limiting space in sliding connection with the limiting pin, a wall body between the reciprocating cavity and the iron scrap groove is in running fit with a connecting rod fixedly connected with the left side of the limiting block, the connecting rod is positioned in the iron scrap groove and is fixedly connected with an extrusion block, the bottom wall of the iron scrap groove is provided with a vertical part at the other side of the oil pipe, the piston ejector rod has no words and the right supporting block is fixedly connected in the iron chip groove.

On the basis of the technical scheme, the extrusion device further comprises a bevel gear rotating groove positioned on the right side of the separation cavity, the rotating shaft is positioned in the bevel gear rotating groove and fixedly connected with a transmission bevel gear, the rear wall of the iron chip groove is provided with a sliding groove, the sliding groove and a spline shaft which is in rotational fit with a wall body between the bevel gear rotating grooves are positioned, the spline shaft is positioned in the bevel gear rotating groove and is in splined connection with a mobile bevel gear which can be meshed with the transmission bevel gear, a third ring groove is formed in the mobile bevel gear, the bottom wall of the bevel gear rotating groove is provided with a vertical part on the other side of the oil pipe, a piston slide rod which is in rotational fit with the third ring groove is arranged in the oil pipe, the spline shaft is positioned in the sliding groove and fixedly connected with a rack gear, and, the rack and pinion is located fixedly connected with connecting rod in the iron chip groove, the iron chip groove antetheca is provided with rotatable release piece, the iron chip groove left side is provided with the opening, cutting oil passageway downside intercommunication has the cutting oil tank.

The invention has the beneficial effects that: through cutting oil before getting into water cutting oil, the filter screen filters the precipitate and the iron fillings of cutting oil, after precipitate and iron fillings accumulate certain quality, be pushed the separating tank in with precipitate and iron fillings separation, when separated iron fillings get into the iron fillings groove and reach certain quality, can be fully compressed, wait for the quality of next filter screen to reach the requirement after, pushed the organism, thereby the time of iron fillings compressed has been guaranteed, improve the quality that the iron fillings compressed, more convenient storage is collected.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings needed in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments of the present invention, and it is obvious for those skilled in the art to obtain other drawings without creative efforts.

FIG. 1 is a schematic view of an overall water tank device for separating iron chips and precipitates from a waste liquid in a numerical control process;

FIG. 2 is a schematic view of the structure in the direction A-A in FIG. 1;

fig. 3 is an enlarged view of a part of the mechanism of the reciprocating chamber 93 in fig. 1;

FIG. 4 is an enlarged view of a portion of the one-way slot 92 of FIG. 1;

fig. 5 is a schematic view of the structure in the direction B-B in fig. 4.

Detailed Description

The invention will now be described in detail with reference to fig. 1-5, for convenience of description, the following orientations will now be defined: the up, down, left, right, and front-back directions described below correspond to the up, down, left, right, and front-back directions in the projection relationship of fig. 1 itself.

Referring to fig. 1 to 5, a water tank device for separating iron filings and precipitates in waste liquid in numerical control machining according to an embodiment of the present invention includes a water tank body 89, a cutting oil channel 43 is provided in the water tank body 89, a push groove 44 is provided on the left side of the upper end of the cutting oil channel 43, a push device is provided in the push groove 44, the push device includes a push block 45 slidably engaged with the push groove 44, a filter screen 42 is provided in the cutting oil channel 43, the push block 45 can push out the cutting oil precipitates and iron filings filtered by the cutting oil channel 43, the right side of the cutting oil channel 43 is communicated with a separation cavity 39, a separation device is provided in the separation cavity 39, the separation device includes a rotation shaft 67 rotatably engaged with the left wall of the separation cavity 39, a magnetic thread groove 62 is provided on the left side of the rotation shaft 67, a magnetic groove 65 not provided on the right side of the rotation cylinder 64 and communicated with the magnetic thread groove 62, when the deposit is pushed behind the disengagement chamber 39, take magnetism thread groove 62 to hold iron fillings, iron fillings groove 26 has been seted up to disengagement chamber 39 downside, be provided with extrusion device in the iron fillings groove 26, extrusion device is including being located iron fillings groove 26 with between the disengagement chamber 39 and the spread groove 33 of intercommunication, disengagement chamber 39 left side downside has been seted up and has been located the left sediment of spread groove 33 collects the chamber 63, after precipitate and iron fillings separate, iron fillings will fall into sediment collection chamber 63 is collected, falls into iron fillings groove 26 prepares to extrude into the piece.

In addition, in one embodiment, the pushing-out device further comprises a rack groove 10 communicated with the left side of the pushing groove 44, a sliding rack 12 fixedly connected with the pushing block 45 on the right side is in sliding fit in the rack groove 10, a connecting spring 11 is connected between the sliding rack 12 and the left wall of the rack groove 10, a bevel gear linkage groove 51 is formed in the lower side of the rack groove 10, a connecting shaft 53 is rotatably connected to the bottom wall of the bevel gear linkage groove 51, a rotating half gear 46 meshed with the sliding rack 12 is fixedly connected in the rack groove 10 by the connecting shaft 53, a sliding bevel gear 50 is in spline connection with the connecting shaft 53 in 5, a second annular groove 49 is formed in the sliding bevel gear 50, a vertical part on one side of an oil path 56 is fixedly arranged on the top wall of the bevel gear linkage groove 51, and a piston moving rod 48 rotatably connected with the second annular groove 49 is in sliding fit in, a bevel gear meshing groove 16 is formed in the left side of the bevel gear linkage groove 51, a motor shaft 15 is rotatably matched with the left wall of the bevel gear meshing groove 16, the motor shaft 15 is fixedly connected with a central bevel gear 52 which is positioned in the bevel gear linkage groove 51 and can be meshed with the sliding bevel gear 50, the motor shaft 15 is positioned in the bevel gear meshing groove 16 and is fixedly connected with a connecting bevel gear 14, the motor shaft 15 extends leftwards to the tail end and is connected with a working motor 13 embedded in the inner wall in a power mode, a vertical part at the other side of the oil way 56 is arranged on the top wall at the left side of the separation cavity 39, a piston weighing rod 55 which is in sliding fit with the oil way 56 is fixedly connected at the bottom of the filter screen 42, a weighing spring 54 is connected between the filter screen 42 and the bottom wall of the separation cavity 39, when the sediment filtered by the filter screen 42 and the iron filings reach a certain mass, the central bevel gear 52 is engaged with the sliding bevel gear 50 to push the iron filings and the sediment out of the separation.

In addition, in one embodiment, the separating device further includes a transmission groove 58 located on the left side of the separating chamber 39, a torsion spring 66 is connected between the left wall of the separating chamber 39 and the left wall of the rotating cylinder 64, a transmission gear 60 is fixedly connected to the rotation shaft 67 located in the transmission groove 58, a half-toothed shaft 91 located on the lower side of the rotation shaft 67 is rotatably connected to the right wall of the transmission groove 58, a transmission half-gear 57 engaged with the transmission gear 60 is fixedly connected to the transmission groove 58, a bevel gear one-way groove 92 is formed on the lower side of the bevel gear linkage groove 51, the half-toothed shaft 91 extends to the left to the bevel gear one-way groove 92 and is rotatably connected with a one-way shaft 69, a matching groove 73 is formed in the one-way shaft 69, a matching block 74 is fixedly connected to the half-toothed shaft 91 located in the matching groove 73, and a top wall 70 is, a one-way block 72 which is in one-way abutting and rotating with the matching block 74 is in sliding fit with the 7, a one-way spring 71 is connected between the one-way block 72 and the top wall of the one-way groove 70, a driving bevel gear 75 is fixedly connected with the one-way shaft 69 in the bevel gear one-way groove 92, a driven bevel gear 76 which is meshed with the driving bevel gear 75 is fixedly connected with the connecting shaft 53 in the bevel gear one-way groove 92, a charged slide rail 41 is fixedly connected with the top wall of the separation cavity 39, a slide rail 40 is fixedly connected with the left side of the charged slide rail 41, a slide pin 61 is slidably connected with the charged thread groove 62 and the non-charged groove 65, an electromagnetic rod 59 which is slidably connected with the charged slide rail 41 and the slide rail 40 is fixedly connected with the upper side of the slide pin 61, when the electromagnetic rod 59 slides on the charged slide rail 41, the slide pin 61, the slide pin 61 loses magnetism.

In addition, in one embodiment, the extruding device further includes a bevel gear transmission groove 22 located at the lower side of the bevel gear engagement groove 16, a rotating shaft 18 with a wall body rotationally matched between the bevel gear transmission groove 22 and the bevel gear engagement groove 16, the rotating shaft 18 is located in the bevel gear engagement groove 16 and is fixedly connected with an engagement bevel gear 17 engaged with the connection bevel gear 14, the rotating shaft 18 is located in the bevel gear transmission groove 22 and is splined with a spline bevel gear 21, a first ring groove 20 is formed in the spline bevel gear 21, a vertical part at one side of an oil pipe 27 is arranged on the top wall of the bevel gear transmission groove 22, the oil pipe 27 is in sliding fit with the first ring groove 20 rotationally connected with the first ring groove 20, a reciprocating cavity 93 is formed at the lower side of the sediment collection cavity 63, and a transmission shaft 68 is rotationally matched with a wall body between the reciprocating cavity 93 and the bevel gear, the transmission shaft 68 is positioned in the bevel gear transmission groove 22 and is fixedly connected with a rotating bevel gear 23 capable of being meshed with the spline bevel gear 21, the transmission shaft 68 is positioned in the reciprocating cavity 93 and is fixedly connected with a rotating bevel gear 80, the rear wall of the reciprocating cavity 93 is in running fit with an extending shaft 82, the extending shaft 82 is positioned in the reciprocating cavity 93 and is fixedly connected with a driven bevel gear 79 meshed with the rotating bevel gear 80, the extending shaft 82 is positioned in the reciprocating cavity 93 and is fixedly connected with a rotating wheel 83 positioned in front of the driven bevel gear 79, the rotating wheel 83 is fixedly connected with a limiting pin 81, the reciprocating cavity 93 is in running fit with a limiting block 78, the limiting block 78 is provided with a limiting space 77 in sliding connection with the limiting pin 81, a connecting rod 84 in running fit with the left side of the limiting block 78 is arranged on the wall body between the reciprocating cavity 93 and the iron chip groove 26, the connecting rod 84 is located fixedly connected with extrusion block 24 in iron chip groove 26, the perpendicular part of oil pipe 27 opposite side has been seted up to iron chip groove 26 diapire, sliding fit has piston ejector pin 28 in oil pipe 27, piston ejector pin 28 has no words fixed connection right branch stay 31 in iron chip groove 26, works as iron chip accumulates certain quality in iron chip groove 26, spline bevel gear 21 with rotating bevel gear 23 meshes, extrusion block 24 presses iron fillings into the piece.

In addition, in one embodiment, the extruding device further includes a bevel gear rotating groove 38 located on the right side of the separating cavity 39, the rotating shaft 67 is located in the bevel gear rotating groove 38 and fixedly connected with a transmission bevel gear 37, the rear wall of the iron chip groove 26 is provided with a sliding groove 86, a spline shaft 34 is located between the sliding groove 86 and the bevel gear rotating groove 38 and is in wall body rotating fit with the wall body, the spline shaft 34 is located in the bevel gear rotating groove 38 and is in spline connection with a mobile bevel gear 36 capable of being meshed with the transmission bevel gear 37, a third ring groove 94 is formed in the mobile bevel gear 36, the bottom wall of the bevel gear rotating groove 38 is provided with a vertical part on the other side of the oil pipe 27, a piston slide rod 35 rotationally connected with the third ring groove 94 is in the oil pipe 27, the spline shaft 34 is located in the, sliding fit has in sliding tray 86 with rack and pinion 85 meshed rack and pinion 87, rack and pinion 87 is located fixedly connected with connecting rod 84 in iron chip groove 26, iron chip groove 26 antetheca is provided with rotatable release piece 32, iron chip groove 26 left side is provided with opening 88, cutting oil passageway 43 downside intercommunication has cutting oil tank 90, after iron fillings extrusion blocking in iron chip groove 26, next the filter screen 42 reaches the certain quality and is released the back, connecting rod 84 can be released the iron fillings that compress into the piece.

In the initial state, the weighing spring 54 is in a relaxed state, the push block 45 is positioned in the push groove 44, the connecting shaft 53 is meshed with the sliding bevel gear 50, the rotating bevel gear 23 is meshed with the spline bevel gear 21, the return spring 29 is in a relaxed state, the torsion spring 66 is in a relaxed state, the electromagnetic rod 59 is positioned on the left side of the rotating cylinder 64, and the transmission bevel gear 37 is not meshed with the moving bevel gear 36.

When the numerical control machine tool performs cutting operation, the operation motor 13 is started, the cutting oil in the cutting oil tank 90 is pumped into the machining center for cooling and then enters the water tank body 89 through the cutting oil channel 43 again, the cutting oil is filtered by the filter screen 42 and then enters the cutting oil tank 90 again, the oxidation precipitates of the iron filings and the cutting oil are filtered on the filter screen 42, when the iron filings and the precipitates on the filter screen 42 are accumulated, the piston weighing rod 55 continuously descends, when the filter screen 42 is accumulated to a certain mass, the oil pressure in the oil channel 56 enables the sliding bevel gear 50 to be meshed with the central bevel gear 52, the motor shaft 15 rotates to drive the central bevel gear 52 to enable the connecting shaft 53 to rotate, the rotating half gear 46 is driven to rotate, the push block 45 pushes the iron filings and the precipitates on the filter screen 42 into the separation cavity 39, the iron filings and the precipitates are disengaged with the rotation of the rotating half gear, the sliding rack 12 returns to the rack slot 10 again, the filter screen 42 returns to the original position again, at this time, the rotating half gear 46 rotates reversely to drive the connecting shaft 53 to rotate reversely, the driven bevel gear 76 rotates reversely to drive the driving bevel gear 75 to rotate, the one-way spring 71 drives the matching block 74 to rotate so that the half gear 91 rotates, the half gear 91 rotates to drive the transmission half gear 57 to rotate for one circle, so that the transmission gear 60 rotates, thereby driving the rotating shaft 67 to rotate so that the rotating cylinder 64 rotates, it is noted that, in the process of rotating the connecting shaft 53 forwardly, the one-way block 72 cannot drive the matching block 74 to rotate due to the shape of the one-way block 72, at this time, the magnetic thread slot 62 with magnetic force adsorbs iron filings, deposits fall into the deposit collecting cavity 63, the rotating cylinder 64 rotates so that the electromagnetic rod 59 moves leftwards, and the electromagnetic rod 59 obtains magnetism under the action, with the iron filings in the magnetic thread groove 62 being continuously adsorbed on the electromagnetic rod 59, with the movement of the electromagnetic rod 59 to the slide rail 40, the electromagnetic rod 59 loses magnetism, the accumulated iron filings without the magnetic groove 65 fall into the iron chip groove 26, with the full disengagement of the rotation of the transmission half gear 57 with the transmission gear 60, under the action of the torsion spring 66, the rotation cylinder 64 rotates back to the original position, after the iron filings in the iron chip groove 26 reach a certain mass, the piston top rod 28 descends to increase the oil pressure in the oil pipe 27, so that the spline bevel gear 21 is engaged with the rotation bevel gear 23, the piston slide rod 35 is engaged with the transmission bevel gear 37, the spline bevel gear 21 is engaged with the rotation bevel gear 23 to drive the transmission shaft 68 to rotate, so that the driven bevel gear 79 rotates, the limiting block 78 moves left and right to fully press the iron filings to the right wall to be extruded into a block, and the next time the filter screen 42, during the process of returning the sliding rack 12 to the rack groove 10, the transmission bevel gear 37 drives the spline shaft 34 to rotate, so that the rack gear 87 moves forwards, the connecting rod 84 pushes out the iron filings, and then the rotating shaft 67 rotates reversely, so that the rack gear 87 returns to the sliding groove 86 again, and the weight 25 is called to return to the original position, so that the cycle is repeated.

The invention has the beneficial effects that: through cutting oil before getting into water cutting oil, the filter screen filters the precipitate and the iron fillings of cutting oil, after precipitate and iron fillings accumulate certain quality, be pushed the separating tank in with precipitate and iron fillings separation, when separated iron fillings get into the iron fillings groove and reach certain quality, can be fully compressed, wait for the quality of next filter screen to reach the requirement after, pushed the organism, thereby the time of iron fillings compressed has been guaranteed, improve the quality that the iron fillings compressed, more convenient storage is collected.

The above description is only for the purpose of illustrating the preferred embodiments of the present invention and is not to be construed as limiting the invention, and any modifications, equivalents, improvements and the like that fall within the spirit and principle of the present invention are intended to be included therein.

Claims (5)

1. The utility model provides a water tank device of iron fillings and precipitate in separation waste liquid in numerical control processing, includes the water tank organism, its characterized in that: the cutting oil separation device is characterized in that a cutting oil channel is formed in the water tank body, a push groove is formed in the left side of the upper end of the cutting oil channel, a push device is arranged in the push groove and comprises a push block in sliding fit with the push groove, a filter screen is arranged in the cutting oil channel, the push block can push out cutting oil sediments and scrap iron filtered by the cutting oil channel, the right side of the cutting oil channel is communicated with a separation cavity, a separation device is arranged in the separation cavity and comprises a rotating shaft in rotating fit with the left wall of the separation cavity, a magnetic thread groove is arranged on the left side of the rotating shaft, a non-magnetic groove communicated with the magnetic thread groove is arranged on the right side of the rotating cylinder, when the sediments are pushed into the separation cavity, the magnetic thread groove can suck the scrap iron, a scrap groove is formed in the lower side of the separation cavity, and an extrusion device is arranged in the scrap groove, the extrusion device is including being located the iron chip groove with the spread groove that communicates between the separation chamber, the left downside of separation chamber has been seted up and has been located the left sediment of spread groove is collected the chamber, precipitate and iron fillings separation back, iron fillings will fall into the sediment is collected the chamber and is collected, falls into the iron chip groove prepares to extrude into the piece.

2. The water tank device for separating iron filings and sediments in waste liquid in numerical control processing as claimed in claim 1, characterized in that: the pushing device further comprises a rack groove communicated with the left side of the pushing groove, a sliding rack fixedly connected with the pushing block is arranged on the right side of the rack groove in a sliding fit manner, a connecting spring is connected between the sliding rack and the left wall of the rack groove, a bevel gear linkage groove is formed in the lower side of the rack groove, the bottom wall of the bevel gear linkage groove is rotatably connected with a connecting shaft, the connecting shaft is positioned in the rack groove and fixedly connected with a rotating half gear meshed with the sliding rack, the connecting shaft is positioned in the internal spline and connected with a sliding bevel gear, a second annular groove is formed in the sliding bevel gear, a vertical part on one side of an oil way is fixedly arranged on the top wall of the bevel gear linkage groove, a piston moving rod rotatably connected with the second annular groove is arranged in the oil way in a sliding fit manner, a bevel gear meshing groove is formed in the left, the motor shaft is located in the bevel gear linkage groove and fixedly connected with a central bevel gear capable of being meshed with the sliding bevel gear, the motor shaft is located in the bevel gear meshing groove and fixedly connected with a connecting bevel gear, the motor shaft extends leftwards to the tail end and is connected with a working motor embedded in the inner wall in a power mode, the top wall of the left side of the separation cavity is provided with a vertical part of the other side of the oil way, the bottom of the filter screen is fixedly connected with a piston weighing rod matched with the oil way in a sliding mode, and a weighing spring is connected between the filter screen and the.

3. The water tank device for separating iron filings and sediments in waste liquid in numerical control processing as claimed in claim 1, characterized in that: the separating device also comprises a transmission groove positioned on the left side of the separating cavity, a torsional spring is connected between the left wall of the separating cavity and the left wall of the rotating cylinder, the rotating shaft is positioned in the transmission groove and is fixedly connected with a transmission gear, the right wall of the transmission groove is rotatably connected with a half-tooth shaft positioned on the lower side of the rotating shaft, the half-tooth shaft is silent, the transmission half-gear meshed with the transmission gear is fixedly connected in the transmission groove, the lower side of the bevel gear linkage groove is provided with a bevel gear one-way groove, the half-tooth shaft extends to the left side of the bevel gear one-way groove and is rotatably connected with a one-way shaft, the one-way shaft is internally provided with a matching groove, the half-tooth shaft is positioned in the matching groove and is fixedly connected with a matching block, the top wall of the one-way shaft is provided with a one-way groove, the, the one-way shaft is positioned in the bevel gear one-way groove and is fixedly connected with a driving bevel gear, the connecting shaft is positioned in the bevel gear one-way groove and is fixedly connected with a driven bevel gear meshed with the driving bevel gear, the top wall of the separation cavity is fixedly connected with an electrified slide rail, the left side of the electrified slide rail is fixedly connected with a slide rail, the electrified thread groove and the non-electrified groove are slidably connected with a slide pin, and the upper side of the slide pin is fixedly connected with an electromagnetic rod slidably connected with the electrified slide rail and the slide rail.

4. The water tank device for separating iron filings and sediments in waste liquid in numerical control processing as claimed in claim 1, characterized in that: the extruding device also comprises a bevel gear transmission groove positioned on the lower side of the bevel gear meshing groove, a rotating shaft of which the wall body is in running fit with the bevel gear meshing groove is positioned between the bevel gear transmission groove and the bevel gear meshing groove, the rotating shaft is positioned in the bevel gear meshing groove and fixedly connected with a meshing bevel gear meshed with the connecting bevel gear, the rotating shaft is positioned in the bevel gear transmission groove and is in spline connection with a spline bevel gear, a first annular groove is formed in the spline bevel gear, the top wall of the bevel gear transmission groove is provided with a vertical part on one side of an oil pipe, the oil pipe is in running fit with the first annular groove which is in running connection with the first annular groove, the lower side of the sediment collection cavity is provided with a reciprocating cavity, the reciprocating cavity is in running fit with the wall body between the bevel gear transmission grooves and is provided with a transmission shaft, the transmission shaft is positioned in the reciprocating cavity and is fixedly connected with a rotary bevel gear, the back wall of the reciprocating cavity is in running fit with an extension shaft, the extension shaft is positioned in the reciprocating cavity and is fixedly connected with a driven bevel gear meshed with the rotary bevel gear, the extension shaft is positioned in the reciprocating cavity and is fixedly connected with a rotating wheel positioned at the front side of the driven bevel gear, the rotating wheel is fixedly connected with a limiting pin, the reciprocating cavity is in sliding connection with a limiting block, the limiting block is provided with a limiting space in sliding connection with the limiting pin, a wall body between the reciprocating cavity and the iron scrap groove is in running fit with a connecting rod fixedly connected with the left side of the limiting block, the connecting rod is positioned in the iron scrap groove and is fixedly connected with an extrusion block, the bottom wall of the iron scrap groove is provided with a vertical part at the other side of the oil pipe, the piston ejector rod has no words and the right supporting block is fixedly connected in the iron chip groove.

5. The water tank device for separating iron filings and sediments in waste liquid in numerical control processing as claimed in claim 1, characterized in that: the extrusion device also comprises a bevel gear rotating groove positioned on the right side of the separation cavity, the rotating shaft is positioned in the bevel gear rotating groove and fixedly connected with a transmission bevel gear, the rear wall of the iron chip groove is provided with a sliding groove, the sliding groove and a spline shaft which is in rotational fit with the wall body between the bevel gear rotating grooves are in splined connection, the spline shaft is positioned in the bevel gear rotating groove and is in splined connection with a mobile bevel gear which can be meshed with the transmission bevel gear, a third ring groove is formed in the mobile bevel gear, the bottom wall of the bevel gear rotating groove is provided with a vertical part on the other side of the oil pipe, a piston slide rod which is in rotational connection with the third ring groove is in sliding fit in the oil pipe, the spline shaft is positioned in the sliding groove and is fixedly connected with a rack gear, a rack gear which is meshed with the rack, the iron chip groove antetheca is provided with rotatable release piece, the iron chip groove left side is provided with the opening, cutting oil passageway downside intercommunication has the cutting oil tank.

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