CN210731859U - Cutting fluid circulation system and corresponding cnc engraving and milling machine - Google Patents

Abstract

The utility model provides a cutting fluid circulation system and corresponding cnc engraving and milling machine, cnc engraving and milling machine include cutting fluid circulation system, base platform, processing platform, main shaft module and water conservancy diversion mechanism. The cutting fluid circulating system is arranged on the peripheral side of the base table and used for recycling and reusing cutting fluid generated in the machining process of the machine tool, and the flow guide mechanism is arranged on the base table and used for guiding the cutting fluid on the base table to the cutting fluid circulating system. Cutting fluid circulation system includes water conservancy diversion platform, first collection box, first filtering component, second collection box, second filtering component, conveyer pipe and transfer pump, through the collection box of water conservancy diversion platform with cutting fluid direction base platform both sides, and recovery efficiency is high, and through the conveyer pipe intercommunication between two collection boxes, exports the use by a transfer pump to the cutting fluid of first collection box recovery, and part utilization is high, and is with low costs.

Description

Cutting fluid circulation system and corresponding cnc engraving and milling machine

Technical Field

The utility model relates to a machining equipment field, in particular to cutting fluid circulation system and corresponding cnc engraving and milling machine.

Background

The cutting fluid is an industrial liquid used for cooling and lubricating a cutter and a workpiece in the metal cutting and grinding process, a filtering and recovering system is mostly arranged on a machine tool needing to be sprayed with the cutting fluid to filter and recover the cutting fluid, a cutting fluid recovering device is arranged on one side of the machine tool in the prior art, the problem of low recovering speed of the cutting fluid exists, the cutting fluid recovering devices are arranged on multiple sides, the cutting fluid recovering devices on each side are respectively provided with a corresponding infusion pump, the cost is high, the diversion of the cutting fluid is poor, and the recovering efficiency of the cutting fluid is low.

Therefore, it is desirable to provide a cutting fluid circulation system and a corresponding engraving and milling machine to solve the above-mentioned problems.

SUMMERY OF THE UTILITY MODEL

The utility model provides a cutting fluid circulation system and corresponding cnc engraving and milling machine, the cnc engraving and milling machine carries out the water conservancy diversion to cutting fluid circulation system with the cutting fluid on the pedestal through water conservancy diversion mechanism, cutting fluid circulation system passes through the collection box of water conservancy diversion platform with cutting fluid direction pedestal both sides, the recovery efficiency is high, and through the conveyer pipe intercommunication between two collection boxes, carry out the export use to the cutting fluid of first collection box recovery by an transfer pump, the part utilization ratio is high, low cost, it is low to solve cutting fluid recovery unit recovery rate among the prior art, and is with high costs, poor to the water conservancy diversion of cutting fluid, the problem that the recovery efficiency to cutting fluid is low.

In order to solve the technical problem, the utility model adopts the technical scheme that: a cutting fluid circulating system is arranged on the peripheral side of a machine tool and used for recovering and reusing cutting fluid generated in the process of machining a workpiece by the machine tool, and comprises:

the guide platform is provided with a plurality of guide outlets and is butted on the periphery of the machine tool and used for guiding the cutting fluid to the guide outlets;

the first recovery tank is arranged at one end of the bottom of the diversion platform, and two ends of the top of the first recovery tank are respectively provided with a first liquid inlet which is opposite to the corresponding guide outlet;

the first filtering assembly is arranged on the first liquid inlet and is used for filtering the cutting liquid entering the first recovery tank;

the second recovery tank is arranged at the other end of the bottom of the diversion platform, and two ends of the top of the second recovery tank are respectively provided with a second liquid inlet which is opposite to the corresponding guide outlet;

the second filtering assembly is arranged on the second liquid inlet and is used for filtering the cutting liquid entering the second recovery tank;

the conveying pipe is used for communicating the inner cavity of the first recovery box with the inner cavity of the second recovery box; and

and the infusion pump is connected to one end of the first recovery box, the input end of the infusion pump is positioned in the first recovery box, and the output end of the infusion pump is connected with the output pipe to output the cutting fluid.

The utility model discloses in, first filtering component includes that top and bottom link up mutually first framework and setting are in first filter layer in the first framework be provided with in the first framework and be used for supporting the first backup pad of first filter layer, first backup pad comprises violently indulging crisscross a plurality of first support bars.

The first recovery box is provided with a first positioning groove for accommodating the first frame body, the inner wall of the first positioning groove is provided with a first fixing strip for supporting the first frame body, and a first filter plate is arranged between the first frame body and the first fixing strip.

Furthermore, the first filter plate is made of hard materials, a set distance is reserved between the first filter layer and the first filter plate so that cutting fluid can flow, and filter holes in the first filter layer and filter holes in the first filter plate are arranged in a staggered mode.

In the utility model, the second filtering component comprises a second frame body with a top end and a bottom end communicated with each other and a second filtering layer arranged in the second frame body, a second supporting plate for supporting the second filtering layer is arranged in the second frame body, and the second supporting plate is composed of a plurality of second supporting strips which are staggered transversely and longitudinally;

a second positioning groove for arranging the second frame body is formed in the second recovery box, a second fixing strip for supporting the second frame body is arranged on the inner wall of the second positioning groove, and a second filter plate is arranged between the second frame body and the second fixing strip;

the second filter is made of hard materials, the second filter layer and the second filter are separated by a set distance for flowing of cutting fluid, and filter holes in the second filter layer are staggered with filter holes in the second filter.

The utility model discloses still include an use the cnc engraving and milling machine of above-mentioned cutting fluid circulation system, it still includes:

a base table;

a processing platform; the base is arranged on the base platform in a sliding mode;

the main shaft module is arranged on the base platform through a cross beam frame and is positioned above the processing platform so as to process the workpiece on the processing platform;

the flow guide mechanism is arranged on the base platform and used for guiding the cutting fluid on the base platform to the flow guide outlet;

the flow guide platform comprises an avoiding groove, wherein the middle part of the avoiding groove is used for arranging the base platform.

In the utility model, the flow guide mechanism comprises a motor, a flow guide screw rod and an extension plate, and two opposite sides of the base platform are taken as length sides, and the other two sides are taken as width sides;

the cutting fluid cutting machine is characterized in that a first guide groove is formed in the base table along the extension direction of the length side face, a second guide groove in butt joint with the first guide groove is formed in the extension plate, output ports are formed in two sides of the second guide groove and are located above the first inlet, a guide screw is arranged in the first guide groove and extends into the second guide groove, and a motor is connected to one end, far away from the second guide groove, of the guide screw to drive the guide screw to rotate, so that cutting fluid on the base table is pushed to the output ports.

Furthermore, the two sides of the base platform are both provided with the first diversion trenches, and two ends of the first diversion trenches are respectively communicated to the end faces of the two ends of the base platform.

In addition, two sides of the first diversion trench are provided with first diversion inclined planes for guiding the cutting fluid to the first diversion trench, and two sides of the second diversion trench are provided with second diversion inclined planes for guiding the cutting fluid to the second diversion trench.

In the utility model, the guide platform comprises first guide plates on two opposite sides and second guide plates on the other two sides, the first guide plates are inclined plates, the two first guide plates are respectively butted with two length sides of the base platform, and the lower side of the first guide plate is butted with the top surface of the base platform in a flush manner;

two the second guide plate respectively with two width sides butt joint of base platform, just the second guide plate is less than the top surface of base platform first collection box with the top of second collection box all is provided with one the second guide plate, the second guide plate includes the main part board at middle part and connects the auxiliary plate of main part board both sides, the main part board with the auxiliary plate all with the extending direction of width side is unanimous, the auxiliary plate is the swash plate in order to be used for with the cutting fluid direction the main part board, the delivery port sets up on the main part board.

The utility model discloses compare in prior art, its beneficial effect is: the utility model discloses an engraving and milling machine carries out the water conservancy diversion to cutting fluid circulation system through water conservancy diversion mechanism with the cutting fluid on the pedestal, and cutting fluid circulation system leads the collection box of pedestal both sides with the cutting fluid through the water conservancy diversion platform, and recovery efficiency is high, and through the conveyer pipe intercommunication between two collection boxes, exports the use by the cutting fluid of a transfer pump to the recovery of first collection box, and part utilization is high, and is with low costs.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings required to be used in the embodiments are briefly introduced below, and the drawings in the following description are only corresponding drawings of some embodiments of the present invention.

Fig. 1 is the structure schematic diagram of the engraving and milling machine of the present invention.

Fig. 2 is the structure diagram of the engraving and milling machine after the cross beam frame and the main shaft module are removed.

Fig. 3 is a schematic structural diagram of the cutting fluid circulation system of the present invention.

Fig. 4 is a schematic structural view of the structure of fig. 2 without a cutting fluid circulation system.

Fig. 5 is a schematic structural diagram of the first recycling box and the second recycling box of the cutting fluid circulating system of the present invention.

Fig. 6 is an exploded view of the first filter assembly of fig. 5.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by the skilled in the art without creative work belong to the protection scope of the present invention.

In the present invention, the directional terms, such as "up", "down", "front", "back", "left", "right", "inner", "outer", "side", "top" and "bottom", refer to the orientation of the drawings, and the directional terms are used for illustration and understanding, but not for limiting the present invention.

The terms "first," "second," and the like in the terms of the present invention are used for descriptive purposes only and are not to be construed as indicating or implying relative importance, nor should they be construed as limiting in any way.

In the present invention, unless otherwise expressly specified or limited, the terms "mounted," "connected," and "secured" are to be construed broadly, e.g., the connection may be a detachable connection or a connection in a unitary structure; can be mechanically or electrically connected; either directly or indirectly through intervening media, either internally or in any other relationship. The specific meaning of the above terms in the present invention can be understood according to specific situations by those skilled in the art.

The machine tool in the prior art is provided with the cutting fluid recovery device on one side, so that the problem of low recovery speed of the cutting fluid exists, the cutting fluid recovery devices are arranged on multiple sides, the cutting fluid recovery devices on each side are provided with corresponding infusion pumps, the cost is high, the diversion of the cutting fluid is poor, and the recovery efficiency of the cutting fluid is low.

The following is the preferred embodiment of the present invention, which can solve the above technical problems.

Please refer to fig. 1, wherein fig. 1 is a schematic structural diagram of an engraving and milling machine according to the present invention.

In the drawings, elements having similar structures are denoted by the same reference numerals.

The utility model provides an engraving and milling machine, it includes base platform 11, processing platform 12, main shaft module 13, water conservancy diversion mechanism 15 and cutting fluid circulation system.

The cutting fluid circulation system is mounted on the peripheral side of the base table 11, and is used for recovering and reusing the cutting fluid generated in the workpiece machining process by the machine tool.

The processing platform 12 is slidably disposed on the base table 11.

The spindle module 13 is disposed on the base table 11 via a cross beam frame 111, and is located above the machining platform 12 to machine a workpiece on the machining platform 12.

The guide mechanism 15 is disposed on the base 11, and guides the cutting fluid on the base 11 to the guide outlet 1423.

The machining platform 12 is provided with a plurality of mounting grooves 121 (the mounting grooves in the drawings are not marked one by one), the mounting grooves 121 penetrate through the end face of the machining platform 12, and the flow guide mechanism 15 is preferably arranged at two ends of the mounting grooves 121, so that the cutting fluid can flow to the flow guide mechanism through the mounting grooves 121 more efficiently.

Referring to fig. 2 and 4, fig. 2 is a schematic structural view of the engraving and milling machine after the cross beam frame and the main shaft module are removed, and fig. 4 is a schematic structural view of the structure in fig. 2 after the cutting fluid circulation system is removed.

Specifically, the diversion mechanism 15 includes a motor 151, a diversion screw 152, and an extension plate 153, and for convenience of description and understanding, two opposite sides of the base table 11 are taken as a length side, and the other two sides are taken as a width side, as shown in fig. 1, the upper side and the lower side of the base table 11 are taken as the length side, and the left side and the right side are taken as the width side, that is, the side where the first recovery tank 16 is located is taken as the width side.

A first flow guide groove 112 is formed in the base table 11 along the extension direction of the length side surface, a second flow guide groove 1532 butted with the first flow guide groove 112 is formed in the extension plate 153, output ports 1531 are formed in two sides of the second flow guide groove 1532, and the output ports 1531 are located above the first liquid inlet;

the guide screw 152 is disposed in the first guide groove 112 and extends into the second guide groove 1532, the motor 151 is connected to one end of the guide screw 152 away from the second guide groove 1532 to drive the guide screw 152 to rotate, so that the cutting fluid on the base table 11 is pushed to the output port 1531, the cutting fluid can be discharged into the first recovery tank 16 as much as possible, the infusion pump 1A is connected to the first recovery tank 16, and the output efficiency of the cutting fluid is high.

Wherein, all be provided with first guiding gutter 112 in the both sides of base platform 11, simultaneously corresponding, all be provided with water conservancy diversion mechanism 15 in the both sides of base platform 11, the both ends of first guiding gutter 112 link up respectively to the terminal surface at base platform 11 both ends on, the water conservancy diversion path is long, and the water conservancy diversion is effectual, and motor 151 fixed connection is on the terminal surface of base platform 11, simple to operate.

In addition, the first guide slopes 113 for guiding the cutting fluid to the first guide grooves 112 are disposed on two sides of the first guide grooves 112, so that the cutting fluid can more efficiently flow along the extension direction of the first guide grooves 112, and the second guide slopes for guiding the cutting fluid to the second guide grooves 1532 are disposed on two sides of the second guide grooves 1532, so as to improve the efficiency of outputting the cutting fluid from the output port 1531.

Referring to fig. 3, fig. 5 and fig. 6, wherein fig. 3 is a schematic structural view of a cutting fluid circulation system of the present invention, fig. 5 is a schematic structural view of a first recycling box and a second recycling box of the cutting fluid circulation system of the present invention, and fig. 6 is a schematic structural view of an explosion of the first filtering assembly in fig. 5.

The cutting fluid circulation system in this embodiment includes a diversion platform 14, a first recovery tank 16, a first filter assembly 19, a second recovery tank 17, a second filter assembly 18, a delivery pipe 1B, and an infusion pump 1A.

The guide platform 14 is provided with a plurality of guide outlets 1423, the guide platform 14 is butted on the periphery of the base platform 11 and is used for guiding the cutting fluid to the guide outlets 1423, and the guide platform 14 includes an avoiding groove 143 in the middle for arranging the base platform 11.

The first recycling box 16 is disposed at one end of the bottom of the diversion platform 14, and the first liquid inlets are disposed at two ends of the top of the first recycling box 16, so that the cutting fluid can be recycled quickly, the layout is reasonable, and the space is saved.

A first filter assembly 19 is provided on the first inlet port for filtering the cutting fluid entering the first recovery tank 16.

The second collection box 17 sets up the other end in water conservancy diversion platform 14 bottom, all is provided with the second inlet at the both ends at second collection box 17 top, and is fast to the recovery of cutting fluid, and is rationally distributed, saves space, and first inlet and second inlet distribute in the four corners of base platform 11, and recovery efficiency is high, and the second inlet is relative with corresponding export 1423 to receive the cutting fluid of export 1423 water conservancy diversion.

A second filter assembly 18 is provided on the second inlet port for filtering the cutting fluid entering the second recovery tank 17.

The conveying pipe 1B is used for communicating an inner cavity of the first recovery tank 16 with an inner cavity of the second recovery tank 17, so that the cutting fluid recovered in the second recovery tank 17 is guided into the first recovery tank 16 to be absorbed by the conveying pump 1A for output and utilization.

The infusion pump 1A is connected to one end of the first recovery tank 16 through the transfer tank 1A1, the input end of the infusion pump 1A is positioned in the transfer tank 1A1, the inner cavity of the transfer tank 1A1 is communicated with the inner cavity of the first recovery tank 16, and the output end of the infusion pump 1A is connected with the output pipe, so that the cutting fluid in the first recovery tank 16 can be absorbed and output and utilized through the output pipe.

As shown in fig. 3, the diversion platform 14 includes first diversion plates 141 on two opposite sides and second diversion plates 142 on the other two sides, the first diversion plates 141 are sloping plates, the two first diversion plates 141 are butted with two length sides of the pedestal 11 respectively, and the lower side of the first diversion plate 141 is butted with the top surface of the pedestal 11 in a flush manner, so that the cutting fluid splashed onto the first diversion plate 141 is guided onto the pedestal 11, and the diversion can be driven to conduct diversion rapidly through the diversion mechanism 15.

The two second guide plates 142 are respectively butted with two width side surfaces of the pedestal 11, the second guide plates 142 are lower than the top surface of the pedestal 11, and one second guide plate 142 is arranged above the first recovery tank 16 and the second recovery tank 17;

the second guide plate 142 includes a main body plate 1421 at the middle and auxiliary plates 1422 connected to both sides of the main body plate 1421, the main body plate 1421 and the auxiliary plates 1422 are both aligned with the extension direction of the width side, the auxiliary plates 1422 are inclined plates for guiding the cutting fluid to the main body plate 1421, the outlet 1423 is disposed on the main body plate 1421, and the main body plate 1421 and the auxiliary plates 1422 are connected to form a groove structure, so that the cutting fluid flowing to the second guide plate 142 can flow to the outlet 1423 quickly.

As shown in fig. 6, the first filter assembly 19 includes a first frame 191 having a top end and a bottom end penetrating each other, and a first filter layer 192 disposed in the first frame 191, a first support plate 1911 for supporting the first filter layer 192 is disposed in the first frame 191, and the first support plate 1911 is composed of a plurality of first support bars staggered in the transverse and longitudinal directions.

The first recycling box 16 is provided with a first positioning groove 161 for accommodating the first frame 191, the inner wall of the first positioning groove 161 is provided with a first fixing strip for supporting the first frame 191, and one side of the first positioning groove 161 penetrates through the side plate of the first recycling box 16, so that the first filter assembly 19 can be conveniently drawn out from the first positioning groove 161.

In addition, a first filter plate 193 is disposed between the first frame 191 and the first fixing bar, the first filter plate 193 is preferably made of a hard material, the first filter layer 192 and the first filter plate 193 are spaced apart from each other by a predetermined distance for the flow of the cutting fluid, and the filter holes of the first filter layer 192 are disposed to be staggered from the filter holes of the first filter plate 193;

the set distance between the first filter layer 192 and the first filter plate 193 can be set to be small so that the first filter plate 193 can support the foreign matter as the foreign matter passes through the filter holes on the first filter layer 192, and the small set distance can prevent the foreign matter from flowing to the filter holes on the first filter plate 193, thereby improving the filtering quality and the filtering efficiency.

In the present invention, the second filtering component 18 includes a second frame body with a top end and a bottom end communicated with each other and a second filtering plate arranged in the second frame body, a second supporting plate for supporting the second filtering plate is arranged in the second frame body, and the second supporting plate is composed of a plurality of second supporting bars which are staggered horizontally and longitudinally;

a second positioning groove for arranging a second frame body is formed in the second recovery box 17, a second fixing strip for supporting the second frame body is arranged on the inner wall of the second positioning groove, and a second filter plate is arranged between the second frame body and the second fixing strip;

the second filter is hard material, sets for the distance at a distance between second filter and the second filter in order to be used for the cutting fluid to flow, and the filtration pore on the second filter sets up with staggering with the filtration pore on the second filter.

The structure of the second filter assembly 18 is the same as that of the first filter assembly 19, and is not shown by reference numerals in the drawings and is not described herein.

The utility model discloses a theory of operation: when the spindle module 13 processes a workpiece on the processing platform 12 and sprays cutting fluid, the cutting fluid flows from the processing platform 12 to the base platform 11, wherein most of the cutting fluid flows to the flow guide mechanism 15 along the mounting groove 121 on the processing platform 12;

the two sides of the diversion mechanism 15 are provided with first diversion slopes 113, so that the cutting fluid flows to the first diversion trench 112, and the motor 151 drives the diversion screw 152 in the first diversion trench 112 to rotate, thereby rapidly and efficiently driving the cutting fluid to flow to the output port 1531, then to flow to the first filtering component 19 through the output port 1423, and to flow into the first recovery tank 16 after being filtered, and the filtered cutting fluid can be output and utilized by the infusion pump 1A;

on the other hand, a small portion of the cutting fluid flows onto the second flow guiding plate 14, flows to the guiding outlet 1423 by the flow guiding of the second flow guiding plate 14, then flows to the first filtering assembly 19 or the second filtering assembly 18, and flows into the corresponding first recovery tank 16 or the second recovery tank 17 after being filtered, and the cutting fluid in the second recovery tank 17 flows into the first recovery tank 16 through the delivery pipe 1B, so as to be absorbed by the fluid infusion pump 1A for output and utilization.

Thus, the process of recycling the cutting fluid by the engraving and milling machine of the preferred embodiment is completed.

The cutting fluid circulation system of this preferred embodiment carries out the water conservancy diversion to the cutting fluid circulation system through water conservancy diversion mechanism with the cutting fluid on the base platform, and the cutting fluid circulation system leads the collection box of cutting fluid guide base platform both sides through the water conservancy diversion platform, and recovery efficiency is high, and through the conveyer pipe intercommunication between two collection boxes, exports the cutting fluid of the recovery of first collection box by an transfer pump and uses, and part utilization is high, and is with low costs.

In summary, although the present invention has been described with reference to the preferred embodiments, the above-described preferred embodiments are not intended to limit the present invention, and those skilled in the art can make various changes and modifications without departing from the spirit and scope of the present invention, so that the scope of the present invention shall be determined by the scope of the appended claims.

Claims (10)

1. A cutting fluid circulation system is installed on the peripheral side of a machine tool and used for recovering and reusing cutting fluid generated in the machining process of a workpiece by the machine tool, and is characterized by comprising:

the guide platform is provided with a plurality of guide outlets and is butted on the periphery of the machine tool and used for guiding the cutting fluid to the guide outlets;

the first recovery tank is arranged at one end of the bottom of the diversion platform, and two ends of the top of the first recovery tank are respectively provided with a first liquid inlet which is opposite to the corresponding guide outlet;

the first filtering assembly is arranged on the first liquid inlet and is used for filtering the cutting liquid entering the first recovery tank;

the second recovery tank is arranged at the other end of the bottom of the diversion platform, and two ends of the top of the second recovery tank are respectively provided with a second liquid inlet which is opposite to the corresponding guide outlet;

the second filtering assembly is arranged on the second liquid inlet and is used for filtering the cutting liquid entering the second recovery tank;

the conveying pipe is used for communicating the inner cavity of the first recovery box with the inner cavity of the second recovery box; and

and the infusion pump is connected to one end of the first recovery box, the input end of the infusion pump is positioned in the first recovery box, and the output end of the infusion pump is connected with the output pipe to output the cutting fluid.

2. The cutting fluid circulation system according to claim 1, wherein the first filter assembly comprises a first frame body having a top end and a bottom end penetrating therethrough, and a first filter layer disposed in the first frame body, wherein a first support plate for supporting the first filter layer is disposed in the first frame body, and the first support plate is composed of a plurality of first support bars staggered in the longitudinal and transverse directions.

3. The cutting fluid circulation system according to claim 2, wherein a first positioning groove for receiving the first frame body is provided on the first recovery tank, a first fixing bar for supporting the first frame body is provided on an inner wall of the first positioning groove, and a first filter plate is provided between the first frame body and the first fixing bar.

4. The cutting fluid circulation system according to claim 3, wherein the first filter plate is a hard material, the first filter layer is spaced apart from the first filter plate by a predetermined distance for the flow of the cutting fluid, and the filter holes of the first filter layer are formed to be offset from the filter holes of the first filter plate.

5. The cutting fluid circulation system according to claim 1, wherein the second filter assembly comprises a second frame body with a top end and a bottom end communicated with each other and a second filter layer arranged in the second frame body, a second support plate for supporting the second filter layer is arranged in the second frame body, and the second support plate is composed of a plurality of second support strips which are staggered transversely and longitudinally;

a second positioning groove for arranging the second frame body is formed in the second recovery box, a second fixing strip for supporting the second frame body is arranged on the inner wall of the second positioning groove, and a second filter plate is arranged between the second frame body and the second fixing strip;

the second filter is made of hard materials, the second filter layer and the second filter are separated by a set distance for flowing of cutting fluid, and filter holes in the second filter layer are staggered with filter holes in the second filter.

6. An engraving and milling machine using the cutting fluid circulating system according to any one of claims 1 to 5, further comprising:

a base table;

a processing platform; the base is arranged on the base platform in a sliding mode;

the main shaft module is arranged on the base platform through a cross beam frame and is positioned above the processing platform so as to process the workpiece on the processing platform;

the flow guide mechanism is arranged on the base platform and used for guiding the cutting fluid on the base platform to the flow guide outlet;

the flow guide platform comprises an avoiding groove, wherein the middle part of the avoiding groove is used for arranging the base platform.

7. The engraving and milling machine of claim 6, wherein the guide mechanism comprises a motor, a guide screw and an extension plate, and two opposite sides of the base platform are taken as length sides, and the other two sides are taken as width sides;

the cutting fluid cutting machine is characterized in that a first guide groove is formed in the base table along the extension direction of the length side face, a second guide groove in butt joint with the first guide groove is formed in the extension plate, output ports are formed in two sides of the second guide groove and are located above the first inlet, a guide screw is arranged in the first guide groove and extends into the second guide groove, and a motor is connected to one end, far away from the second guide groove, of the guide screw to drive the guide screw to rotate, so that cutting fluid on the base table is pushed to the output ports.

8. The engraving and milling machine of claim 7, wherein the first diversion trench is disposed on both sides of the base platform, and both ends of the first diversion trench penetrate through end surfaces of both ends of the base platform respectively.

9. The engraving and milling machine according to claim 7, wherein first guide slopes for guiding the cutting fluid to the first guide grooves are provided on both sides of the first guide grooves, and second guide slopes for guiding the cutting fluid to the second guide grooves are provided on both sides of the second guide grooves.

10. The engraving and milling machine of claim 7, wherein the guide platform comprises first guide plates on two opposite sides and second guide plates on the other two opposite sides, the first guide plates are inclined plates, the two first guide plates are respectively butted with two length sides of the base platform, and the lower side of the first guide plate is butted with the top surface of the base platform in a flush manner;

two the second guide plate respectively with two width sides butt joint of base platform, just the second guide plate is less than the top surface of base platform first collection box with the top of second collection box all is provided with one the second guide plate, the second guide plate includes the main part board at middle part and connects the auxiliary plate of main part board both sides, the main part board with the auxiliary plate all with the extending direction of width side is unanimous, the auxiliary plate is the swash plate in order to be used for with the cutting fluid direction the main part board, the delivery port sets up on the main part board.

Images