CN217668253U - Machining center hydraulic oil return oil cooling body - Google Patents

Abstract

The utility model belongs to the technical field of numerical control machining center, especially, machining center hydraulic oil return cooling body, including the cooling post of seting up the cooling chamber, first installing port has been seted up to the upper end inner wall of cooling post, and the inner wall of first installing port passes through the liquid inlet cylinder that bearing fixedly connected with outward surface was cross structure, and first installing port has been seted up to the inside wall of first installing port, and the liquid inlet cylinder is located the first ring gear of the outer fixed surface of first installing port department. This machining center hydraulic oil return oil cooling body, through setting up the honeycomb duct, water conservancy diversion post and semiconductor refrigeration piece, reached and will flow to the lower extreme of water conservancy diversion dish through the hydraulic oil water conservancy diversion that the honeycomb duct was on the water conservancy diversion dish, make in the second guiding gutter of hydraulic oil flow to water conservancy diversion post through the honeycomb duct water conservancy diversion, in to the hydraulic oil water conservancy diversion, through the cooling of semiconductor refrigeration piece to the cooling water, cool down the temperature in the cooling chamber, the in-process that flows at hydraulic oil carries out the effect of efficient cooling to hydraulic oil.

Description

Machining center hydraulic oil return oil cooling body

Technical Field

The utility model relates to a numerical control machining center technical field especially relates to a machining center hydraulic oil return cooling body.

Background

The numerical control machining center is a high-efficiency automatic machine tool which consists of mechanical equipment and a numerical control system and is suitable for machining complex parts. The numerical control machining center is one of numerical control machines with the highest yield and the most extensive application in the world. The machining device has stronger comprehensive machining capacity, can finish more machining contents after the workpiece is clamped once, has higher machining precision, can finish batch workpieces with medium machining difficulty, has the efficiency 5 to 10 times that of common equipment, can finish machining which cannot be finished by a plurality of common equipment, and is more suitable for single-piece machining with complex shapes and high precision requirements or medium and small batch multi-variety production. The functions of milling, boring, drilling, tapping, cutting threads and the like are integrated on one device, so that the device has multiple processing procedures. The machining center is classified into a horizontal machining center and a vertical machining center according to the spatial position of the main shaft during machining. The method is classified into a boring and milling machining center and a combined machining center according to the process application. The special classification according to the function is single worktable, double worktable and multi-worktable processing center. A machining center with a single shaft, double shafts, three shafts and a replaceable spindle box;

machining center need cool down to the hydraulic oil in the hydraulic system for the hydraulic system that mechanical operation system provided hydraulic oil in the use, and current hydraulic oil when cooling, need draw external world with hydraulic oil through oil pipe and dispel the heat, and hydraulic oil flows in heat dissipation oil pipe, and heat dissipation oil pipe's pipe diameter is less, is not convenient for dispel the heat to hydraulic oil at the hydraulic oil flow in-process, has reduced the radiating efficiency to hydraulic oil.

SUMMERY OF THE UTILITY MODEL

When cooling down based on current hydraulic oil, need lead to the external world with hydraulic oil through oil pipe and dispel the heat, be not convenient for dispel the heat to hydraulic oil at the mobile in-process of hydraulic oil, reduced the technical problem to the radiating efficiency of hydraulic oil, the utility model provides a machining center hydraulic oil return cooling body.

The utility model provides a machining center hydraulic oil return oil cooling body, including the cooling post of seting up the cooling chamber, first installing port has been seted up to the upper end inner wall of cooling post, the inner wall of first installing port passes through the feed liquor section of thick bamboo that bearing fixedly connected with outward appearance personally submits cross structure, first installing port has been seted up to the inside wall of first installing port, the feed liquor section of thick bamboo is located the first ring gear of outer fixed surface of first installing port department, the second installing port has been seted up to the upper surface of cooling post, the inner wall fixed mounting of second installing port has driving motor, driving motor's main shaft outer fixed surface cup joint with the drive gear of first ring gear meshing.

Preferably, the outer surface of the middle part of the liquid inlet cylinder is fixedly connected with blades, the inner side edge of the bottom of the liquid inlet cylinder is provided with water leakage holes distributed in an annular array, the inner side wall of the upper end of the cooling cavity is provided with a first guide groove for increasing the length of a flow path of hydraulic oil, the inner wall of the middle part of the cooling cavity is fixedly sleeved with a guide disc, and the inner surface of the middle part of the guide disc is movably sleeved with the outer surface of the lower end of the liquid inlet cylinder;

through above-mentioned technical scheme, reached and driven the blade through the rotation of liquid inlet cylinder and rotate, and then accelerated the air flow in the cooling chamber, and then increased the effect to the cooling efficiency of hydraulic oil.

Preferably, the upper surface of the flow guide disc is provided with a plurality of connecting holes which are distributed in an annular array and are in a spiral structure, the tail ends of the connecting holes penetrate through and extend to the lower surface of the flow guide disc, and the inner wall of each connecting hole is fixedly connected with a flow guide pipe;

through the technical scheme, the effect of installing the honeycomb duct through the connecting hole is achieved.

Preferably, the lower surface of the flow guide disc is fixedly connected with a flow guide column, the outer surface of the flow guide column is provided with a second flow guide groove in a spiral structure, and the inner wall of the flow guide pipe is perpendicular to the inner wall of the top end of the second flow guide groove;

through above-mentioned technical scheme, reached and carried out the water conservancy diversion to hydraulic oil through the second guiding gutter on the water conservancy diversion post to through the honeycomb duct perpendicular with the second guiding gutter, make the effect that flows to in the second guiding gutter that hydraulic oil in the honeycomb duct can be accurate.

Preferably, an annular storage cavity for storing cooling water is formed in the inner wall of the cooling column, and a semiconductor refrigerating sheet for cooling the cooling water in the annular storage cavity is fixedly mounted on the inner top wall of the annular storage cavity;

through above-mentioned technical scheme, it deposits the chamber through the annular and deposits the cooling water and deposit to deposit the cooling water in the chamber through the semiconductor refrigeration piece and carry out refrigerated effect to the annular.

Preferably, a connecting port is formed in the inner wall of one side of the annular storage cavity, one end of the connecting port penetrates through and extends to the inner wall of the cooling cavity, and a heat dissipation ring is fixedly sleeved on the inner wall of the lower end of the cooling cavity;

through above-mentioned technical scheme, reached through the effect that the temperature of heat dissipation ring with cooling water evenly conducts to the cooling chamber in.

Preferably, the inner wall of the connector is fixedly connected with a temperature conduction column connected with the outer surface of the heat dissipation ring, and the inner wall of the heat dissipation ring is fixedly connected with a heat dissipation sheet for increasing the cooling effect in the cooling cavity;

through above-mentioned technical scheme, reached the effect that increases the radiating efficiency of heat dissipation ring through the piece that dispels the temperature.

The utility model provides a beneficial effect does:

through setting up the honeycomb duct, water conservancy diversion post and semiconductor refrigeration piece, reached and will flow to the lower extreme of water conservancy diversion dish through the hydraulic oil water conservancy diversion of honeycomb duct on the water conservancy diversion dish, and make in the second guiding gutter of hydraulic oil stream extremely water conservancy diversion post through the honeycomb duct water conservancy diversion, in to the hydraulic oil water conservancy diversion, through the cooling of semiconductor refrigeration piece to the cooling water, cool down the temperature in the cooling chamber, and then carry out the effect of efficient cooling to hydraulic oil at the in-process that hydraulic oil flows.

Drawings

Fig. 1 is a schematic view of a hydraulic oil return oil cooling mechanism of a machining center according to the present invention;

fig. 2 is a perspective view of a liquid inlet cylinder structure of a hydraulic oil return oil cooling mechanism of a machining center provided by the utility model;

fig. 3 is the utility model provides a machining center hydraulic oil return oil cooling body's guide post structure stereogram.

In the figure: 1. cooling the column; 101. a cooling chamber; 2. a first mounting port; 3. a liquid inlet cylinder; 4. a first mounting cavity; 5. a first ring gear; 6. a second mounting opening; 7. a drive motor; 8. a drive gear; 9. a blade; 10. a water leakage hole; 11. a first diversion trench; 12. a flow guide disc; 13. connecting holes; 14. a flow guide pipe; 15. a flow guide column; 16. a second guiding gutter; 17. an annular storage chamber; 18. a semiconductor refrigeration sheet; 19. a connecting port; 20. a heat dissipation ring; 21. a temperature conducting column; 22. a Chinese medicinal tablet for dissipating heat.

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.

Referring to fig. 1-3, a machining center hydraulic oil return oil cooling mechanism, including the cooling column 1 of seting up cooling chamber 101, first installing port 2 has been seted up to the upper end inner wall of cooling column 1, the inner wall of first installing port 2 passes through bearing fixedly connected with outward appearance and personally submits the feed liquor section of thick bamboo 3 of cross structure, first installing port 4 has been seted up to the inside wall of first installing port 2, the first ring gear 5 of outer fixed surface that feed liquor section of thick bamboo 3 is located first installing port 4 department, second installing port 6 has been seted up to the upper surface of cooling column 1, the inner wall fixed mounting of second installing port 6 has driving motor 7, driving motor 7's main shaft outer fixed surface cup joints drive gear 8 with first ring gear 5 meshing.

The middle part outer fixed surface of the feed cylinder 3 is connected with the blade 9, the inboard border department in bottom of feed cylinder 3 sets up the hole 10 that leaks that is the distribution of annular array, the first guiding gutter 11 that is used for increasing hydraulic oil flow path length is offered to the upper end inside wall of cooling chamber 101, the fixed guiding disc 12 that has cup jointed of middle part inner wall of cooling chamber 101, and the middle part internal surface of guiding disc 12 cup joints with the lower extreme surface activity of feed cylinder 3, it rotates to have reached through the rotatory moving blade 9 of feed cylinder 3, and then accelerate the air flow in the cooling chamber 101, and then increase the effect to the cooling efficiency of hydraulic oil.

A plurality of connecting holes 13 that are the helical structure that are that the annular array distributes are seted up to the upper surface of guiding disc 12, and the end of connecting hole 13 runs through and extends to the lower surface of guiding disc 12, the inner wall fixedly connected with honeycomb duct 14 of connecting hole 13, the effect of installing honeycomb duct 14 through connecting hole 13 has been reached, the lower fixed surface of guiding disc 12 is connected with guide post 15, second guiding gutter 16 that is the helical structure is seted up to the surface of guide post 15, and the top inner wall mutually perpendicular of the inner wall of honeycomb duct 14 and second guiding gutter 16, reached and carried out the water conservancy diversion to hydraulic oil through second guiding gutter 16 on the honeycomb duct 15, and through honeycomb duct 14 perpendicular and second guiding gutter 16, make the effect of flowing to in the second guiding gutter 16 of hydraulic oil in the honeycomb duct 14 can the accuracy.

The inner wall of cooling column 1 is offered the annular that is used for depositing the cooling water and is deposited chamber 17, the interior roof fixed mounting that the chamber 17 was deposited to the annular is used for depositing the cooling water in chamber 17 and carries out refrigerated semiconductor refrigeration piece 18 to the annular, it deposits chamber 17 and deposits the cooling water to have reached through the annular, and deposit the cooling water in chamber 17 through semiconductor refrigeration piece 18 and carry out refrigerated effect, connector 19 has been seted up to one side inner wall that chamber 17 was deposited to the annular, connector 19's one end runs through and extends to the inner wall of cooling chamber 101, the fixed cover of lower extreme inner wall of cooling chamber 101 has been cup jointed and has been scattered warm ring 20, reached through the even effect of conducting to cooling chamber 101 in of the temperature of scattered warm ring 20 with the cooling water.

The inner wall of the connecting port 19 is fixedly connected with a temperature guiding column 21 connected with the outer surface of the heat dissipation ring 20, and the inner wall of the heat dissipation ring 20 is fixedly connected with a heat dissipation sheet 22 for increasing the cooling effect in the cooling cavity 101, so that the effect of increasing the heat dissipation efficiency of the heat dissipation ring 20 through the heat dissipation sheet 22 is achieved.

Through setting up honeycomb duct 14, water conservancy diversion post 15 and semiconductor refrigeration piece 18, reached through honeycomb duct 14 with flowing to the lower extreme of the hydraulic oil water conservancy diversion to water conservancy diversion dish 12 on the water conservancy diversion dish 12, and make in the hydraulic oil that flows through the honeycomb duct 14 water conservancy diversion flows to the second guiding gutter 16 of water conservancy diversion post 15, in to the hydraulic oil water conservancy diversion, through the cooling of semiconductor refrigeration piece 18 to the cooling water, cool down the temperature in the cooling chamber, and then carry out the effect of efficient cooling to hydraulic oil at the in-process that hydraulic oil flows.

The working principle is as follows: when the cooling device is used, the driving motor 7 and the semiconductor refrigerating sheet 18 are started, the temperature of cooling water in the annular storage cavity 17 is conducted into the cooling cavity 101 through the temperature conduction column 21 or conducted onto the temperature dissipation ring 20, the temperature dissipation of the cooling water is accelerated through the temperature dissipation sheet 22, hydraulic oil enters from the upper end of the liquid inlet cylinder 3 and flows out of the water leakage hole 10 in the bottom of the liquid inlet cylinder 3, the driving motor 7 drives the driving gear 8 to rotate, the liquid inlet cylinder 3 is driven to rotate through the meshing of the driving gear 8 and the first toothed ring 5, the blades 9 are driven to rotate to accelerate air flow, when the hydraulic oil flows out of the water leakage hole 10, the hydraulic oil flows out in an arc path, the hydraulic oil is attached to the inner wall of the cooling cavity 101 or falls into the first diversion groove 11, the stay time of the hydraulic oil is prolonged, and the hydraulic oil is further primarily cooled;

the primarily cooled hydraulic oil flows into the flow guide disc 12, is guided to the flow guide column 15 through the flow guide pipe 14, is guided to the bottom of the cooling cavity 101 through the second flow guide groove 16, and when the hydraulic oil flows on the flow guide column 15, the cooling effect is increased by the heat dissipation ring 20 and the heat dissipation sheet 22, so that the hydraulic oil is further cooled.

The above, only be the concrete implementation of the preferred embodiment of the present invention, but the protection scope of the present invention is not limited thereto, and any person skilled in the art is in the technical scope of the present invention, according to the technical solution of the present invention and the utility model, the concept of which is equivalent to replace or change, should be covered within the protection scope of the present invention.

Claims (7)

1. The utility model provides a machining center hydraulic oil return oil cooling body, is including offering cooling column (1) of cooling chamber (101), its characterized in that: first installing port (2) have been seted up to the upper end inner wall of cooling column (1), the inner wall of first installing port (2) passes through bearing fixedly connected with outward appearance and personally submits cross structure's feed liquor section of thick bamboo (3), first installation cavity (4) have been seted up to the inside wall of first installing port (2), feed liquor section of thick bamboo (3) are located the first ring gear of outer fixed connection of first installation cavity (4) department (5), second installing port (6) have been seted up to the upper surface of cooling column (1), the inner wall fixed mounting of second installing port (6) has driving motor (7), the main shaft external surface fixed of driving motor (7) cup joint with the drive gear (8) of first ring gear (5) meshing.

2. The machining center hydraulic oil return oil cooling mechanism of claim 1, characterized in that: the middle part of a liquid inlet cylinder (3) surface fixed connection has blade (9), the inboard border department in bottom of a liquid inlet cylinder (3) sets up the hole that leaks (10) that are the distribution of annular array, first guiding gutter (11) that are used for increasing hydraulic oil flow path length are offered to the upper end inside wall of cooling chamber (101), the middle part inner wall of cooling chamber (101) is fixed to have cup jointed guiding disk (12), just the middle part internal surface of guiding disk (12) with the lower extreme surface activity of a liquid inlet cylinder (3) is cup jointed.

3. The machining center hydraulic oil return oil cooling mechanism of claim 2, wherein: the upper surface of guiding disk (12) is seted up a plurality of connecting holes (13) that are the helical structure that are the annular array and distribute, just the end of connecting hole (13) runs through and extends to the lower surface of guiding disk (12), the inner wall fixedly connected with honeycomb duct (14) of connecting hole (13).

4. The machining center hydraulic oil return oil cooling mechanism of claim 3, characterized in that: the lower surface of the diversion disc (12) is fixedly connected with a diversion column (15), a second diversion trench (16) which is of a spiral structure is formed in the outer surface of the diversion column (15), and the inner wall of the diversion pipe (14) is perpendicular to the inner wall of the top end of the second diversion trench (16).

5. The machining center hydraulic oil return oil cooling mechanism of claim 1, characterized in that: the annular chamber (17) of depositing that is used for depositing the cooling water is seted up to the inner wall of cooling column (1), the annular interior roof fixed mounting who deposits chamber (17) is used for right the annular cooling water of depositing in chamber (17) carries out refrigerated semiconductor refrigeration piece (18).

6. The machining center hydraulic oil return oil cooling mechanism of claim 5, wherein: a connecting port (19) is formed in the inner wall of one side of the annular storage cavity (17), one end of the connecting port (19) penetrates through and extends to the inner wall of the cooling cavity (101), and a heat dissipation ring (20) is fixedly sleeved on the inner wall of the lower end of the cooling cavity (101).

7. The machining center hydraulic oil return oil cooling mechanism of claim 6, wherein: the inner wall of the connecting port (19) is fixedly connected with a heat conducting column (21) connected with the outer surface of the heat dissipation ring (20), and the inner wall of the heat dissipation ring (20) is fixedly connected with a heat dissipation sheet (22) used for increasing the cooling effect in the cooling cavity (101).

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