CN213411345U - Cooling device for numerical control cutting fluid - Google Patents

Abstract

The utility model provides a cooling arrangement of numerical control cutting fluid belongs to cutting fluid technical field, including base, staving, lid, first rotating electrical machines, rotary rod, first flabellum and helical blade, the upper surface welding of base is provided with the staving, and the last fixed surface of staving is provided with the lid, and the upper surface central authorities of lid are provided with first rotating electrical machines through the bolt fastening, and the output welding of first rotating electrical machines is provided with the rotary rod. The utility model discloses an open first rotating electrical machines, first rotating electrical machines drives the rotary rod rotatory, the rotary rod drives first flabellum rotatory, first flabellum down bloies, make the outside air enter into the pipeline through the air intake, blow on the cutting fluid in the staving, move toward both sides again, blow off through the air outlet on the lid, reach radiating effect, and through be provided with helical blade on the rotary rod, when making the rotary rod rotatory, mix the cutting fluid through helical blade, prevent that the cutting fluid is the solidification state.

Description

Cooling device for numerical control cutting fluid

Technical Field

The utility model relates to a cutting fluid technical field, more specifically relates to a cooling arrangement of numerical control cutting fluid.

Background

The cutting fluid is prepared by scientifically compounding and matching various super-strong functional additives, and has the characteristics of good cooling performance, lubricating performance, antirust performance, oil removing and cleaning functions, anticorrosion function and easiness in dilution. The defects that the traditional soap-based emulsion is easy to smell in summer, difficult to dilute in winter and poor in antirust effect are overcome, the lathe paint is not affected, and the soap-based emulsion is suitable for cutting and grinding ferrous metal and belongs to the most advanced grinding product at present. The cutting fluid has various indexes superior to those of saponified oil, has the characteristics of good cooling, cleaning, rust prevention and the like, and has the characteristics of no toxicity, no odor, no corrosion to human bodies, no corrosion to equipment, no pollution to the environment and the like.

Current digit control machine tool in use often need cool off and lubricated cutter through the cutting fluid, however current cutting fluid cooling device cooling method is too single to the cutting fluid has the risk of storing improperly, leads to great reduction the effect of cutting fluid, has brought certain inconvenience for people.

Chinese utility model patent with patent publication No. CN211249354U and publication No. 2020, 08 and 14 discloses a cutting fluid cooling device of a numerical control machine tool, which comprises a barrel body, a barrel cover is arranged at the upper end of the barrel body, a base is fixedly arranged at the bottom of the barrel body, a circulating water pump is fixedly arranged at the upper end of the other side of the barrel body, an inlet and an outlet are arranged at the upper end of the circulating water pump, a cutting fluid storage chamber is arranged in the barrel body, a cooling pipeline is arranged between the barrel body and the cutting fluid storage chamber and is communicated with the circulating water pump, the cutting fluid cooling device of the numerical control machine tool can keep the internal cutting fluid to flow by using a stirring shaft and helical blades, avoid the conditions of solidification of the cutting fluid and the like, and can carry out wind power cooling treatment on the internal cutting fluid by using fan blades, reduce the temperature of the cutting fluid, utilize circulating water pump to send external water into cooling tube through the inlet outlet in, make the water in the cooling tube carry out cooling treatment to the cutting fluid, improve the cooling effect, this application structure is more reasonable, and the design is optimized more, but this utility model has following defect:

1. the circulating water pump is used for sending outside water into the cooling pipeline through the water inlet and the water outlet, so that the water in the cooling pipeline is used for cooling the cutting fluid, the water is heated to lead to the rise of the water temperature, the water cannot be recycled, and the water is wasted;

2. the motor is arranged below the cover body, and heat dissipated by the motor is arranged in the barrel body and the cover body, so that the heat is not conveniently dissipated, and the motor is easily damaged;

3. an air inlet device is not arranged between the barrel body and the cover body, so that air blown out by the fan can only flow in the sealing environment between the barrel body and the cover body, and the effect of cooling cutting fluid cannot be achieved. Therefore, the cooling device for the numerical control cutting fluid is designed to solve the problems.

SUMMERY OF THE UTILITY MODEL

The utility model aims at solving the problem of proposing in the above-mentioned background to provide a cooling arrangement of numerical control cutting fluid.

In order to achieve the above object, the utility model provides a following technical scheme: a cooling device for numerical control cutting fluid comprises a base, a barrel body, a cover body, a first rotating motor, a rotating rod, a first fan blade and a spiral blade, wherein the barrel body is welded on the upper surface of the base, the cover body is fixedly arranged on the upper surface of the barrel body, the first rotating motor is fixedly arranged in the center of the upper surface of the cover body through bolts, the rotating rod is welded on the output end of the first rotating motor, the first fan blade is welded on the upper portion of the outer side surface of the rotating rod, the spiral blade is welded on the lower portion of the outer side surface of the rotating rod, an air inlet is observed on the upper surface of the cover body, a pipeline is welded on the bottom of the inner surface of the cover body, air outlets are arranged on the left side surface and the right side surface of the cover body in a penetrating manner, a water inlet valve, the bottom of the left side surface of the barrel body is provided with a blowing device in a penetrating way;

the barrel body comprises an outer shell layer, a water cavity and an inner wall layer, the outer shell layer is fixedly arranged on the outermost surface of the barrel body, the inner wall layer is fixedly arranged on the innermost surface of the barrel body, and the water cavity is formed between the outer shell layer and the inner wall layer;

blowing device is including trunk line, horizontal pipe, auxiliary pipeline, installation pole, second rotating electrical machines and second flabellum, the right side surface of trunk line runs through and is provided with horizontal pipe, the right side surface of horizontal pipe runs through and is provided with many auxiliary pipelines, the inside surface left side welding of trunk line is provided with the installation pole, the right side surface welding of installation pole is provided with the second rotating electrical machines, the right side surface welding of second rotating electrical machines is provided with the second flabellum.

Preferably, the first rotating electric machine and the second rotating electric machine are electrically connected to an external power source through wires.

Preferably, the air inlet penetrates through the upper part of the pipeline.

Preferably, the water inlet valve penetrates through the inner part of the water cavity.

Preferably, the auxiliary pipeline penetrates through the bottom end of the inner part of the water cavity, and the auxiliary pipeline penetrates through the right side surface of the barrel body.

Preferably, the inner wall layer and the secondary pipeline are both made of metal materials with good heat conducting performance.

The utility model provides a cooling arrangement of numerical control cutting fluid has following beneficial effect:

1. this cooling arrangement of numerical control cutting fluid is provided with first flabellum, the pipeline, air intake and air outlet, through opening first rotating electrical machines, first rotating electrical machines drives the rotary rod rotatory, the rotary rod drives first flabellum rotatory, first flabellum down bloies, make the outside air enter into in the pipeline through the air intake, blow on the cutting fluid in the staving, move toward both sides again, blow off through the air outlet on the lid, reach radiating effect, and through be provided with helical blade on the rotary rod, when making the rotary rod rotatory, stir the cutting fluid through helical blade, prevent that the cutting fluid is the solidification state.

2. This cooling arrangement of numerical control cutting fluid is provided with water cavity and blast apparatus, when the cutting fluid in the staving is cooled off to needs, fill up water toward the water cavity through the water intaking valve, and open the second rotating electrical machines on the blast apparatus, the water of water cavity cools off the cutting fluid in the staving, make the temperature of water cavity rise, and it is rotatory to drive the second flabellum through the second rotating electrical machines, the right side is bloied towards the second flabellum, the air flows to horizontal pipe through the trunk line, horizontal pipe flows the auxiliary line again, make the circulation of air in the auxiliary line accelerate, the heat of air flow drive off the aquatic of water cavity, reach radiating effect.

Drawings

Fig. 1 is a schematic sectional view of the overall structure of the present invention.

Fig. 2 is an enlarged schematic structural diagram of fig. 1A of the present invention.

Fig. 3 is a schematic structural view of the blowing device of the present invention.

Fig. 4 is a schematic view of a sectional structure of the blowing device of the present invention.

In FIGS. 1-4: 1-base, 2-barrel, 201-outer shell layer, 202-water cavity, 203-inner wall layer, 3-cover, 4-first rotating motor, 5-rotating rod, 6-first fan blade, 7-helical blade, 8-air inlet, 9-pipeline, 10-air outlet, 11-water inlet valve, 12-liquid outlet valve, 13-blowing device, 1301-main pipeline, 1302-transverse pipe, 1303-auxiliary pipeline, 1304-mounting rod, 1305-second rotating motor and 1306-second fan blade.

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 a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1 to 4, in an embodiment of the present invention, a cooling apparatus for numerically controlled cutting fluid includes a base 1, a barrel 2, a cover 3, a first rotating electrical machine 4, a rotating rod 5, a first fan blade 6 and a spiral blade 7, the barrel 2 is welded to an upper surface of the base 1, the cover 3 is fixed to an upper surface of the barrel 2, the first rotating electrical machine 4 is fixed to a center of an upper surface of the cover 3 by a bolt, the rotating rod 5 is welded to an output end of the first rotating electrical machine 4, the first fan blade 6 is welded to an upper portion of an outer side surface of the rotating rod 5, the spiral blade 7 is welded to a lower portion of the outer side surface of the rotating rod 5, an air inlet 8 is observed on the upper surface of the cover 3, a pipe 9 is welded to a bottom portion of an inner surface of the cover 3, an air outlet 10 is arranged to penetrate through left and right, a liquid outlet valve 12 is arranged at the bottom of the right side surface of the barrel body 2 in a penetrating manner, and a blowing device 13 is arranged at the bottom of the left side surface of the barrel body 2 in a penetrating manner;

the barrel body 2 comprises a shell layer 201, a water cavity 202 and an inner wall layer 203, the shell layer 201 is fixedly arranged on the outermost surface of the barrel body 2, the inner wall layer 203 is fixedly arranged on the innermost surface of the barrel body 2, and the water cavity 202 is formed between the shell layer 201 and the inner wall layer 203;

the blowing device 13 comprises a main pipe 1301, a transverse pipe 1302, auxiliary pipes 1303, mounting rods 1304, a second rotating motor 1305 and second fan blades 1306, the transverse pipe 1302 penetrates through the right side surface of the main pipe 1301, the auxiliary pipes 1303 penetrate through the right side surface of the transverse pipe 1302, the auxiliary pipes 1303 are welded on the left side of the inner surface of the main pipe 1301, the mounting rods 1304 are welded on the left side of the inner surface of the main pipe 1301, the second rotating motor 1305 is welded on the right side surface of the mounting rods 1304, and the second fan blades 1306 are welded on the right side surface of the second rotating motor 1305.

In this embodiment, the first rotating electrical machine 4 and the second rotating electrical machine 1305 are electrically connected to an external power source through wires, so that the external power source provides power to the first rotating electrical machine 4 and the second rotating electrical machine 1305.

In this embodiment, the air inlet 8 penetrates the upper portion of the duct 9, so that the air entering from the air inlet 8 enters the duct 9 and blows downwards.

In this embodiment, the water inlet valve 11 penetrates the water cavity 202, so that water is added into the water cavity 202 through the water inlet valve 11.

In this embodiment, the sub-pipe 1303 penetrates through the bottom end of the inner portion of the water cavity 202, and the sub-pipe 1303 penetrates through the right side surface of the barrel body 2, so that heat is dissipated from the water in the water cavity 202 through the sub-pipe 1303.

In this embodiment, the inner wall layer 203 and the sub-pipe 1303 are made of metal material with good heat conductivity, so that the heat of the cutting fluid in the barrel 2 is absorbed through the inner wall layer 203, and the heat of the water in the water cavity 202 is absorbed through the sub-pipe 1303.

When the cooling device of the numerical control cutting fluid of the utility model is used, firstly, the power is switched on, the water cavity is filled with water through the water inlet valve 11, the first rotating motor 4 and the second rotating motor 1305 are opened, the first rotating motor 4 drives the rotating rod 5 to rotate, the rotating rod 5 drives the first fan blade 6 to rotate, the first fan blade 6 blows air downwards, so that the outside air enters the pipeline 9 through the air inlet 8, blows on the cutting fluid in the barrel body 2, moves towards both sides again, blows out through the air outlet 10 on the cover body 3, and reaches the heat dissipation effect, and the helical blade 7 is arranged on the rotating rod 5, so that the cutting fluid is stirred through the helical blade 7 while the rotating rod 5 rotates, the cutting fluid is prevented from being in a solidification state, the second rotating motor 1305 on the air blowing device 13 is opened, the water in the water cavity 202 cools the cutting fluid in the barrel body 2, so that the temperature uprises, and drives second flabellum 1306 rotatory through second rotating electrical machines 1305, and second flabellum 1306 is right side to blow, and the air flows to horizontal pipe 1302 through trunk line 1301, and horizontal pipe 1302 flows to auxiliary duct 1303 again for circulation of air in the auxiliary duct 1303 accelerates, and the heat of aquatic in the water cavity 202 is taken away in the air flow, reaches radiating effect.

The above is only the preferred embodiment of the present invention, and it should be noted that, for those skilled in the art, without departing from the concept of the present invention, several modifications and improvements can be made, which should also be regarded as the protection scope of the present invention, and these will not affect the effect of the implementation of the present invention and the practicability of the patent.

Claims (6)

1. The utility model provides a cooling arrangement of numerical control cutting fluid, includes base (1), staving (2), lid (3), first rotating electrical machines (4), rotary rod (5), first flabellum (6) and helical blade (7), its characterized in that: the water-saving and water-saving toilet bowl is characterized in that a bowl body (2) is welded on the upper surface of a base (1), a cover body (3) is fixedly arranged on the upper surface of the bowl body (2), a first rotating motor (4) is fixedly arranged in the center of the upper surface of the cover body (3) through bolts, a rotating rod (5) is welded on the output end of the first rotating motor (4), a first fan blade (6) is welded on the upper portion of the outer side surface of the rotating rod (5), a spiral blade (7) is welded on the lower portion of the outer side surface of the rotating rod (5), an air inlet (8) is arranged on the upper surface of the cover body (3) in an observation mode, a pipeline (9) is welded on the bottom of the inner surface of the cover body (3), an air outlet (10) is arranged on the surfaces of the left side and, a liquid outlet valve (12) is arranged at the bottom of the right side surface of the barrel body (2) in a penetrating manner, and a blowing device (13) is arranged at the bottom of the left side surface of the barrel body (2) in a penetrating manner;

the barrel body (2) comprises an outer shell layer (201), a water cavity (202) and an inner wall layer (203), the outer shell layer (201) is fixedly arranged on the outermost surface of the barrel body (2), the inner wall layer (203) is fixedly arranged on the innermost surface of the barrel body (2), and the water cavity (202) is formed between the outer shell layer (201) and the inner wall layer (203);

the blowing device (13) comprises a main pipe (1301), a transverse pipe (1302), an auxiliary pipe (1303), an installation rod (1304), a second rotating motor (1305) and second fan blades (1306), wherein the transverse pipe (1302) penetrates through the right side surface of the main pipe (1301), a plurality of auxiliary pipes (1303) penetrate through the right side surface of the transverse pipe (1302), the installation rod (1304) is welded on the left side of the inner surface of the main pipe (1301), the second rotating motor (1305) is welded on the right side surface of the installation rod (1304), and the second fan blades (1306) are welded on the right side surface of the second rotating motor (1305).

2. The cooling apparatus of a numerically controlled cutting fluid according to claim 1, wherein: the first rotating motor (4) and the second rotating motor (1305) are both electrically connected with an external power supply through wires.

3. The cooling apparatus of a numerically controlled cutting fluid according to claim 1, wherein: the air inlet (8) penetrates through the upper part of the pipeline (9).

4. The cooling apparatus of a numerically controlled cutting fluid according to claim 1, wherein: the water inlet valve (11) penetrates through the inside of the water cavity (202).

5. The cooling apparatus of a numerically controlled cutting fluid according to claim 1, wherein: the auxiliary pipeline (1303) penetrates through the inner bottom end of the water cavity (202), and the auxiliary pipeline (1303) penetrates through the right side surface of the barrel body (2).

6. The cooling apparatus of a numerically controlled cutting fluid according to claim 1, wherein: the inner wall layer (203) and the auxiliary pipeline (1303) are made of metal materials with good heat conducting performance.

Images