KR20220141488A - Tool cooling system of Machine tool - Google Patents

Abstract

The present invention relates to a tool cooling device for a machine tool, comprising: a tool rest body; a turret on which a plurality of tools are mounted and installed on the tool rest body; an indexing unit for rotating the turret; and a cooling unit having a supply passage and a delivery passage and cooling one or more tools mounted on the turret. When the turret is indexed, the delivery passage is selectively communicated with the supply passage depending on an indexing angle of the turret so as to cool a processing tool for processing a workpiece with a cooling fluid delivered through the supply passage, and pre-cool a standby tool.

Description

Tool cooling system of Machine tool

The present invention relates to a tool cooling device for a machine tool, and more particularly, when the turret is indexed, the transmission flow path selectively communicates with the supply flow path according to the indexing angle of the turret, and processes the workpiece with the cooling fluid transmitted through the supply flow path The cooling waiting time can be minimized by cooling the machining tool and pre-cooling the standby tool, and the cooling fluid can be delivered to multiple delivery channels through two supply channels, so that the delivery channel can be flexibly expanded as needed. It relates to a tool cooling system for a machine tool.

In general, a machine tool refers to a machine used for the purpose of machining a metal/non-metal workpiece into a desired shape and size using an appropriate tool by various cutting or non-cutting methods.

Various types of machine tools, including turning centers, vertical/horizontal machining centers, door machining centers, Swiss turns, electric discharge machines, horizontal NC boring machines, CNC lathes, multi-task machines, etc. is being used

Among machine tools, multi-tasking machine means a turning center equipped with a multi-function automatic tool changer (ATC) and tool magazine that performs various machining types such as turning, drilling, tapping, and milling. In the multi-tasking machine, the operator loads the tool required for machining or manually loads the tool into the tool magazine when exchanging it.

In general, various types of machine tools currently used have an operation panel to which a numerical control (NC) or computerized numerical control (CNC) technology is applied. Such an operation panel is provided with various function switches or buttons and a monitor.

In addition, the machine tool is a table on which a workpiece material is seated and transferred for processing the workpiece, a pallet for preparing the workpiece before processing, a spindle that rotates when a tool or workpiece is combined, a tailstock for supporting the workpiece, etc. during processing, a vibration isolator etc. are provided.

In general, in a machine tool, a table, a tool rest, a main shaft, a tailstock, a vibration isolator, etc. are provided with a conveying unit conveying along a conveying axis in order to perform various machining.

In addition, in general, a machine tool uses a plurality of tools for various processing, and a tool magazine or a turret is used as a tool storage place for storing and storing a plurality of tools.

Such a machine tool uses a plurality of tools for various processing, and a tool magazine is used in the form of a tool storage place storing a plurality of tools.

In addition, in general, a machine tool is provided with an automatic tool changer (ATC, Automatic Tool Changer) for withdrawing or receiving a specific tool from the tool magazine by the command of the numerical control unit in order to improve the productivity of the machine tool.

In addition, in general, a machine tool is provided with an automatic pallet changer (APC, Automatic Palette Changer) in order to minimize the non-working time. The automatic pallet changer (APC) automatically exchanges pallets between the workpiece machining area and the workpiece installation area. Pallets may be loaded with workpieces.

In addition, in general, machine tools are largely classified into turning centers and machining centers according to processing methods. In general, the turning center rotates the workpiece, and the machining center performs the machining of the workpiece while the tool rotates.

A turning center, commonly called a lathe, is a device that processes a workpiece by approaching a tool while rapidly rotating a workpiece mounted on a spindle.

The double turning center is equipped with a turret tool rest device for mounting a plurality of tools and indexing the tools required in the machining process.

That is, the tool exchange operation of moving one machining tool working from the machining position in the turning center to the standby position and simultaneously bringing one of the standby tools in the standby position to the machining position is called indexing.

As such, in a machine tool, particularly a turning center, indexing is essentially required at least once for tool exchange during machining.

In addition, the chip and the tool are responsible for most of the heat recovery generated during processing due to the low thermal conductivity of difficult-to-cut materials such as Inconel or titanium, which require cryogenic processing. Accordingly, as the tool is heated during machining, the lifespan becomes very short, and cooling is required during machining to increase the lifespan.

Moreover, it is necessary to pre-cool the standby tool in order to maximize productivity by reducing the machining waiting time.

As such, the turret tool cooling device installed in the conventional turning center cools the tool by supplying cryogenic cooling fluids such as liquid nitrogen and liquid carbon dioxide for cooling and pre-cooling of the tool for processing the difficult-to-cut tool.

However, in the conventional turret tool cooling device, at the moment the turret is indexed for tool exchange, the connection of the cryogenic cooling fluid supply line that essentially supplies the cryogenic cooling fluid must be disconnected and the fluid supply must be cut off. There was a problem in that the leakage of the cryogenic cooling fluid occurred.

In addition, as the conventional turret tool cooling device supplies cryogenic cooling fluid to only one tool, pre-cooling cannot be performed, which increases the machining time and waiting time of the workpiece, thereby reducing productivity, shortening the tool life, and increasing machining costs. There was a problem.

Furthermore, the conventional turret tool cooling device has a problem in that the cryogenic cooling fluid supply line is not directly connected to the tool, and the cooling efficiency is decreased due to the increase in the pipe resistance of the flow path pipe according to the complicated arrangement structure.

In addition, in the conventional turret tool cooling device, when the transmission flow path is expanded, the supply flow path, the adjusting unit, and the base flow path must be provided equally as much as the number of the transmission flow paths, so there is a limitation in the installation space and the cost of parts increases. There was a problem in that the expansion of the euro for this purpose was limited.

Korean Patent Publication No. 10-2014-0056160

The present invention is to solve the above problems, and the present invention is a method for processing a workpiece with a cooling fluid delivered through the supply passage through the delivery passage selectively communicating with the supply passage according to the indexing angle of the turret when the turret is indexed. As the machining tool is cooled and the standby tool is pre-cooled, even when the turret is indexing, the cryogenic cooling fluid is continuously supplied to the machining tool without separation or interruption of the cooling flow, thereby preventing the leakage of the cryogenic cooling fluid and blocking the inflow of chips. , through a structure directly connected to the tool, the cooling efficiency is maximized by reducing the pipe resistance of the delivery channel, and the cooling waiting time can be minimized by pre-cooling the waiting tool while cooling the machining tool. An object of the present invention is to provide a tool cooling device for a machine tool that can deliver a cooling fluid to the delivery passage of

In order to achieve the object of the present invention, a tool cooling apparatus for a machine tool according to the present invention includes a tool rest body; a turret on which a plurality of tools are mounted and installed on the tool rest body; an indexing unit for rotating the turret; and a cooling unit having a supply passage and a delivery passage, and cooling one or more tools mounted on the turret, wherein when the turret is indexed, the delivery passage is formed between the supply passage and the supply passage according to the indexing angle of the turret. It is possible to selectively communicate with the cooling fluid transmitted through the supply passage to cool the machining tool for processing the workpiece and pre-cool the standby tool.

In addition, in another preferred embodiment of the tool cooling device for a machine tool according to the present invention, the transmission flow path may be formed in a part of the indexing unit such that the same number as the supply flow path or one or more more than the supply flow path can

In addition, in another preferred embodiment of the tool cooling device of the machine tool according to the present invention, the indexing unit, the casing portion installed on the tool rest body; a fixing part fixedly installed to the casing part; a rotating part adjacent to the fixing part and rotatably installed inside the casing part; and a driving unit installed on the tool rest body to provide rotational power to the rotating unit.

In addition, in another preferred embodiment of the tool cooling device of the machine tool according to the present invention, the supply flow passage is formed through a part of the fixing portion to receive a cooling fluid for cooling the processing tool is supplied; and a pre-supply flow passage formed to be spaced apart from the machining supply flow passage at a predetermined angle with respect to an indexing shaft in a portion of the fixing part to pre-cool the preliminary tool.

In addition, in another preferred embodiment of the tool cooling apparatus for a machine tool according to the present invention, the angle of formation of the processing supply passage and the preliminary supply passage may be changed according to the number of transmission passages formed in plurality in the rotating part. .

In addition, in another preferred embodiment of the tool cooling apparatus of the machine tool according to the present invention, one side of each of the plurality of transmission passages selectively communicates with the processing supply passage or the preliminary supply passage according to the indexing angle of the turret a communication part extending through the rotating part so as to be formed; and an extension portion bent from the other side of the communication portion to cool the machining tool or pre-cool the standby tool and extend adjacent to the tool mounted on the turret so as to be perpendicular to the indexing axis.

In addition, in another preferred embodiment of the tool cooling apparatus for a machine tool according to the present invention, the arrangement angle between the two adjacent communicating parts with respect to the indexing axis is the forming angle between the processing supply passage and the preliminary supply passage and It may be formed to have the same angle.

In addition, in another preferred embodiment of the tool cooling device for a machine tool according to the present invention, the cooling unit, one side is connected to the cooling fluid supply source, the other side is connected to the supply passage base passage; and a control unit installed on the base flow path to control the supply and blockage of the cooling fluid from the cooling fluid supply source to the supply flow path.

Further, in another preferred embodiment of the tool cooling apparatus for a machine tool according to the present invention, the base flow path, one side is in communication with the cooling fluid supply source for supplying a cooling fluid for cooling the processing tool, the other side is the a processing base passage communicating with the processing supply passage; and a preliminary base passage communicating with the cooling fluid supply source on one side and communicating with the preliminary supply passage on the other side in order to supply a cooling fluid for pre-cooling the standby tool.

In addition, in another preferred embodiment of the tool cooling apparatus for a machine tool according to the present invention, the control unit is installed on the processing base flow path to control the supply or blockage of the cooling fluid from the cooling fluid supply source to the processing supply flow path. a first control unit; and a second control unit installed on the preliminary base flow path to control supply or blockage of the cooling fluid from the cooling fluid supply source to the preliminary supply flow path.

In addition, in another preferred embodiment of the tool cooling device of the machine tool according to the present invention, four communication parts are formed through the rotation part to have a disposition angle of 90 degrees around the indexing axis, and the processing supply passage and the preliminary supply The flow path may be formed through the fixing part so as to have a forming angle of 90 degrees with respect to the indexing axis.

In addition, in another preferred embodiment of the tool cooling device of the machine tool according to the present invention, the first adjusting unit and the second adjusting unit may be formed as a solenoid valve.

In the tool cooling device of the machine tool according to the present invention, when the turret is indexed, the transmission flow path selectively communicates with the supply flow path according to the indexing angle of the turret to cool the machining tool for processing the workpiece with the cooling fluid transmitted through the supply flow path, As the standby tool is pre-cooled, the cooling fluid can be delivered to a plurality of delivery passages through two supply passages, so that the delivery passages can be flexibly expanded as needed. If only two supply channels, adjustment parts, and base flow paths are provided without having to provide the same supply flow path, the control unit, and the base flow path, they are selectively communicated with a plurality of transmission flow paths and the cooling fluid can be transmitted to the tool. It has the effect of minimizing additional installation cost and installation space for expansion.

In addition, the tool cooling device of the machine tool according to the present invention can cool the machining tool with the cooling fluid supplied through the supply passage and the delivery passage and pre-cool the standby tool at the same time, thereby minimizing the tool cooling time to increase the productivity of the machine tool. There is an effect that can be improved.

In addition, in the tool cooling device of the machine tool according to the present invention, the angle of formation of the processing supply passage and the preliminary supply passage is changed according to the number of transmission passages formed in plurality in the rotating part, and between the two adjacent communication parts about the indexing shaft. As the arrangement angle is made to have the same angle as the angle formed between the processing supply passage and the preliminary supply passage, even when the number of delivery passages is expanded, when the turret is indexed, the delivery passage is accurately communicated with the supply passage according to the indexing angle of the turret. Since the cooling fluid can be delivered, the cooling of the machining tool and the pre-cooling of the standby tool can be sufficiently accurately realized, so there is an effect of improving the machining precision by preventing misprocessing due to heat generation in advance.

Furthermore. In the tool cooling device of the machine tool according to the present invention, since the transmission flow path is disposed through the rotating part of the indexing unit formed in the rotary union structure, the cooling flow is not separated or interrupted even when the turret is indexed. As continuous supply is directly possible, it has the effect of preventing leakage of cryogenic cooling fluid and blocking the inflow of chips.

In addition, the tool cooling device of the machine tool according to the present invention is arranged in a structure directly connected to the tool received radially in the turret so that the transmission flow path is angularly divided around the indexing axis, thereby reducing the pipe resistance of the cryogenic cooling fluid delivered to the transmission flow path This has the effect of maximizing the cooling efficiency.

1 shows a perspective view of a tool cooling device of a machine tool according to the present invention viewed from above.
Figure 2 shows a perspective view from the bottom of the tool cooling device of the machine tool according to the present invention.
3 shows a plan view of a tool cooling device of a machine tool according to the present invention.
FIG. 4 is a cross-sectional view taken along line AA shown in FIG. 3 .
FIG. 5 is a cross-sectional view taken along line BB shown in FIG. 3 .
6 is a view showing in detail the supply flow path of the tool cooling device of the machine tool according to the present invention.
7 is a view showing in detail the transmission flow path of the tool cooling device of the machine tool according to the present invention.

Hereinafter, with reference to the drawings of the tool cooling apparatus of the machine tool according to an embodiment of the present invention will be described in detail. The embodiments introduced below are provided as examples so that the spirit of the present invention can be sufficiently conveyed to those skilled in the art. Accordingly, the present invention is not limited to the embodiments described below and may be embodied in other forms. And, in the drawings, the size and thickness of the device may be exaggerated for convenience. Like reference numbers refer to like elements throughout.

Advantages and features of the present invention, and a method of achieving them will become apparent with reference to the embodiments described below in detail in conjunction with the accompanying drawings. However, the present invention is not limited to the embodiments disclosed below, but will be implemented in a variety of different forms, and only these embodiments allow the disclosure of the present invention to be complete, and common knowledge in the art to which the present invention pertains It is provided to fully inform the possessor of the scope of the invention, and the present invention is only defined by the scope of the claims. Like reference numerals refer to like elements throughout. The sizes and relative sizes of layers and regions in the drawings may be exaggerated for clarity of description.

The terminology used herein is for the purpose of describing the embodiments, and therefore is not intended to limit the present invention. In this specification, the singular also includes the plural, unless specifically stated otherwise in the phrase. As used herein, "comprise" and/or "comprising" refers to the presence of one or more other components, steps, operations and/or elements mentioned. or addition is not excluded.

Figure 1 shows a perspective view of the tool cooling device of the machine tool according to the present invention viewed from above, Figure 2 shows a perspective view of the tool cooling device of the machine tool according to the present invention from below.

3 is a plan view of a tool cooling device for a machine tool according to the present invention, and FIG. 4 is a cross-sectional view taken along line A-A shown in FIG. 3 .

5 is a cross-sectional view taken along the line B-B shown in FIG. 3, and FIG. 6 is a detailed view showing the supply flow path of the tool cooling device of the machine tool according to the present invention.

7 is a view showing in detail the transmission flow path of the tool cooling device of the machine tool according to the present invention.

A tool cooling device 1 of a machine tool according to the present invention will be described with reference to FIGS. 1 to 7 . 1 to 7 , the tool cooling device 1 of a machine tool according to the present invention includes a tool rest body 100 , a turret 200 , an indexing unit 300 , and a cooling unit 400 . do.

The tool rest body 100 of the tool cooling device 1 of the machine tool according to the present invention is installed on a part or bed of the body of the machine tool not shown in the drawings.

The turret 200 of the tool cooling device 1 of the machine tool according to the present invention is installed on the tool rest body 100, and a plurality of tools 22 are mounted.

The turret 200 may accommodate various tools such as a cutting tool required for machining a workpiece, a tool used for external turning and internal turning, as well as a tool required for a drill or milling operation.

Specifically, the turret 200 is angularly divided around the indexing axis C to receive a plurality of tools radially.

Although it is illustrated that the turret is divided into 12 angles at an angle of 30 degrees in FIGS. 1 to 2 , the present invention is not limited thereto and may be divided at a desired angle as necessary.

That is, the turret of the tool cooling device of the machine tool according to the present invention is divided into 36 angles at an angle of 10 degrees, 24 angles at a 15 degree angle, or 9 angles at a 40 degree angle, if necessary. , 60 degree angle divided into six angles, 90 degree angle divided into 5 angles, 120 degree angle angle divided into three angles, or 180 degree angle angle divided into two angles may be.

The indexing unit 300 of the tool cooling device 1 of the machine tool according to the present invention is for rotating the turret 200, and for indexing the plurality of tools 22 mounted on the turret 200, the turret and the tool It is installed across the body.

Also, according to a preferred embodiment of the present invention, the indexing unit 20 may be formed as a rotary union.

That is, as shown in FIGS. 1 and 3 to 4 , the indexing unit 300 of the tool cooling device 1 of the machine tool according to the present invention includes a casing part 310 , a fixing part 320 , and a rotating part 330 . ) and/or a driving unit 340 .

The casing part 310 is installed on the tool rest body 100 .

The fixing part 320 is fixedly installed on the casing part 310 . That is, even while the turret is indexing, the fixing unit is fixed to the casing and does not rotate.

In addition, as shown in FIGS. 4 and 5 , the fixing unit may be composed of two blocks.

The rotating part 330 is rotatably installed while adjoining the fixing part 320 in the inside of the casing part 310 .

The rotating part 330 is formed in a hollow cylindrical pipe shape through which the inside is formed, is supported through a bearing inside the casing part, and is rotatably coupled.

In addition, the rotating unit 330 is installed to extend through the turret 200 and rotates according to the driving of the driving unit 340 .

That is, the rotating part 33 is formed to extend through the inside of the turret, and the communication part of the transmission flow path to be described later is disposed inside the through groove along the internal through-groove of the rotating part.

One or more bearings are installed between the fixed part and the rotating part to rotate and support the rotating part so that the rotating part can rotate according to the driving of the driving part.

The driving unit 340 is installed on the tool rest body 100 to provide rotational power to the indexing unit 300 . That is, the driving unit 340 rotates the turret 200 to selectively provide rotational power to the turret 200 to process a workpiece with a desired tool among a plurality of tools 2 mounted on the turret.

Although not necessarily limited thereto, the driving unit 340 may be formed of a servomotor. In addition, the driving unit 340 operates according to the command of the PLC or the numerical control unit.

In addition, the numerical control unit includes NC (numerical control, NC) or CNC (computerized numerical control), and various numerical control programs are built-in.

That is, the numerical control unit has a built-in driving program for the servomotor, which is a driving unit, and a tool operation program, and the corresponding program is automatically loaded and operated according to the driving of the numerical control unit. In addition, the numerical control unit communicates with the main operation unit and PLC by a predetermined protocol.

In addition, the main operation unit includes a screen display program and a data input program according to the screen display selection, and displays a software switch on the display screen according to the output of the screen display program, and controls ON/OFF of the software switch. It recognizes and executes the function of issuing input/output commands for machine operation.

In addition, although not necessarily limited thereto, the main operation unit includes a monitor that is installed on the housing, case, or one side of the machine tool to display various function switches or buttons and various information.

A programmable logic controller (PLC) performs communication according to a predetermined protocol with a numerical control unit or a main operation unit, and performs a function of executing a control command through such communication. That is, the PLC operates by receiving a control command according to the numerical control program of the numerical control unit or the main operation unit.

The cooling unit 400 of the tool cooling device 1 of the machine tool according to the present invention is for cooling one or more tools mounted on the turret 200. Specifically, a cooling fluid supply source 410, a base flow path 420. , a control unit 430 , a supply passage 440 and/or a delivery passage 450 .

1 to 5, the cooling fluid supply source 410 is installed outside the tool cooling device of the machine tool or inside or outside the cover of the machine tool to supply cryogenic cooling fluid to the tool through the cooling passage. store fluid.

Such cryogenic cooling fluid may be formed of liquid nitrogen and liquid carbon dioxide.

One side of the base flow path 420 is connected to a cooling fluid supply source 410 , and the other side is connected to a supply flow path 440 to be described later.

Specifically, the base flow path 420 includes a processing base flow path 421 and a preliminary base flow path 422 .

One side of the processing base flow path 421 communicates with a cooling fluid supply source 410 to supply a cooling fluid for cooling the processing tool, and the other side communicates with a processing supply flow path 441 to be described later.

One side of the preliminary base flow path 422 communicates with a cooling fluid supply source 410 to supply a cooling fluid for pre-cooling the standby tool, and the other side communicates with a preliminary supply flow path 442 to be described later.

That is, when only two of the base flow paths 420 are installed as the processing base flow path 421 and the preliminary base flow path 422 , the cooling fluid can be supplied to a plurality of delivery flow paths as described later.

4 to 5, the control unit 430 is installed on the base flow path 420 to control the supply and blocking of the cooling fluid from the cooling fluid supply source 410 to the supply flow path 440 to be described later. .

Specifically, the adjusting unit 430 includes a first adjusting unit 431 and a second adjusting unit 432 .

The first adjustment unit 431 may be installed on the processing base flow path 421 to supply a cooling fluid from the cooling fluid supply source 410 to a processing supply flow path 441 to be described later or to block the cooling fluid. When supplied, the flow rate of the supplied cooling fluid can be adjusted as needed.

The second control unit 432 is installed on the preliminary base flow path 422 to supply the cooling fluid from the cooling fluid supply source 410 to the preliminary supply flow path 422 to be described later or to block the cooling fluid. When supplied, the flow rate of the supplied cooling fluid can be adjusted as needed.

In addition, the first control unit 431 and the second control unit 432 may be formed of a solenoid valve (Solenoid Valve).

A solenoid valve is an electromagnetic valve, and when electricity passes, the flange rises to open the valve, and when electricity is cut off, the valve automatically closes by the weight of the flange.

As such, as the valve is opened or closed through the control of the numerical control unit, the supply amount of the cryogenic cooling fluid is adjusted to cool the machining tool or pre-cool the standby tool during indexing or workpiece machining.

Accordingly, it is possible to prevent the waste of the cryogenic cooling fluid in advance, to prevent safety accidents in advance, to minimize the processing cost, and to promote the convenience of the operator.

4 and 5 , the supply passage 440 includes a processing supply passage 441 and a preliminary supply passage 422 . As described above, since the supply flow path 440 is formed in the fixed part 320 which is fixed without rotating during the indexing of the turret 200, the supply flow path 440 is also fixed without rotating during the indexing of the turret. .

The processing supply passage 441 is formed through a part of the fixing part 320 to receive a cooling fluid for cooling the processing tool currently being processed.

The preliminary supply flow path 422 is a part of the fixing part 320 for pre-cooling the preliminary tool to be used for the next processing after the machining of the processing tool is completed. It is formed penetratingly spaced apart at a predetermined angle.

That is, the supply passage 440 can supply the cooling fluid to a plurality of delivery passages as described later when only two of the processing supply passage 441 and the preliminary supply passage 422 are installed, like the base passage 420 described above.

4 and 5 , the transmission flow path 450 may be formed in plurality, and the transmission flow path 450 is partially formed in the rotating part 330 that rotates while the turret 200 is indexed as described above. Therefore, the transmission passage 450 is also rotated while the turret 200 is indexing.

One side of the delivery flow path 450 is selectively communicated with the supply flow path, that is, the processing supply flow path and/or the preliminary supply flow path according to the indexing angle of the turret, and the other side of the delivery flow path is turret so that the angle is divided around the indexing axis (C). It is formed to extend through the rotating part 330 so as to be adjacent to any one of a plurality of tools radially accommodated in the .

In addition, the transmission flow path 450 is formed in plurality according to the number of angles divided around the indexing axis (C) axis. Specifically, the transmission flow path of the cooling unit of the tool cooling device of the machine tool according to the present invention may be provided with 36 transmission flow paths when the turret is angularly divided into 10 degrees and 36 angles.

However, in consideration of the diameter of the rotating part 330 or the size of the inner diameter of the through-groove, preferably 2 to 10 transmission passages may be formed.

For example, as shown in FIGS. 1 to 5 , when the turret 200 is divided into 12 angles at an angle of 30 degrees with respect to the indexing axis, 2 to 4 are each one of the tools of the divided turret. Four can be installed adjacent to the tool of

In addition, each of the plurality of transmission passages 450 specifically includes a communication portion 451 and an extension portion 452 .

The communication part 451 is formed to extend through the rotating part 330 so that one side selectively communicates with the processing supply passage 441 or the preliminary supply passage 442 according to the indexing angle of the turret 200 .

The extension portion 452 is bent from the other side of the communication portion 451 to cool the machining tool or pre-cool the standby tool, and adjacent to the tool 2 mounted on the turret 200 so as to be perpendicular to the indexing axis C. extension is formed.

Both the communication part 451 and the extension part 452 may be formed of an insulating tube.

As such, in the tool cooling device of the machine tool according to the present invention, as the transmission flow path is disposed through the rotating part rotated together when the turret of the indexing unit is rotated in a rotary union structure, the cooling flow path is separated or cut off even when the turret is indexed As the continuous supply of cryogenic cooling fluid is possible directly to the tool being machined without it, it is possible to prevent leakage of the cryogenic cooling fluid and block the inflow of chips.

In addition, the tool cooling device of the machine tool according to the present invention is arranged in a structure directly connected to the tool received radially in the turret so that the transmission flow path is angularly divided around the indexing axis, thereby reducing the pipe resistance of the cryogenic cooling fluid delivered to the transmission flow path This has the effect of maximizing the cooling efficiency.

In the tool cooling device 1 of the machine tool according to the present invention, when the turret 200 is indexed, the transmission flow path 450 is selectively communicated with the supply flow path 440 according to the indexing angle of the turret 200, and the supply flow path ( 440), it is possible to cool the machining tool for processing the workpiece with the cooling fluid received through the cooling fluid and pre-cool the standby tool.

That is, when the turret 200 is indexed, the fixing part 320 is fixed without rotating as described above, and the supply passage 440 formed through the fixing part 320 is also fixed.

On the other hand, when the turret 200 is indexed, the rotating unit 330 rotates as described above, and the transmission flow path 450 formed through the rotating unit 330 also rotates.

Therefore, since the supply flow path is fixed, as the transmission flow passage that rotates relative to the supply flow passage rotates, the supply flow passage and the delivery flow passage are selectively communicated according to the indexing angle of the turret 200 .

Specifically, when the communicating part of any one of the plurality of delivery channels communicates with the processing supply channel, the machining tool is cooled. is pre-cooled.

As such, the tool cooling device of the machine tool according to the present invention can cool the machining tool with the cooling fluid supplied through the supply passage and the transfer passage and pre-cool the standby tool at the same time, thereby minimizing the tool cooling time to increase the productivity of the machine tool. can be improved

In addition, the transmission flow path 450 of the tool cooling device 1 of the machine tool according to the present invention is the same number as the supply flow path 440 or a part of the indexing unit 300 so that there is one or more more than the supply flow path 440 . can be formed in

That is, in the present invention, since the supply flow path 440 is composed of two processing supply passages 441 and a preliminary supply passage 442 , the delivery passage 450 may be formed of two or more, that is, two, three, four, or the like.

Accordingly, as described above, if only two of the base flow path 420, the control unit 430 and/or the supply flow path 440 are provided, the transmission flow path selectively communicates with the supply flow path and receives the cooling fluid, so the transmission flow path The number of can be extended to a plurality.

As such, in the tool cooling device of the machine tool according to the present invention, when the turret is indexed, the transmission flow path selectively communicates with the supply flow path according to the indexing angle of the turret, and the cooling fluid delivered through the supply flow path cools the machining tool for processing the workpiece. And as the standby tool is pre-cooled, the cooling fluid can be delivered to multiple delivery flow paths through two supply flow paths, so that the delivery flow path can be flexibly expanded as needed. If there is no need to provide the same number of supply passages, adjustment units, and base oil passages, and only two supply passages, adjustment units, and base oil passages are provided, they are selectively communicated with a plurality of delivery passages and can deliver the cooling fluid to the tool. It is possible to minimize additional installation cost and installation space for flow path expansion.

Referring to FIG. 6 , the angle of formation of the processing supply passage 441 and the preliminary supply passage 442 of the tool cooling device 1 of the machine tool according to the present invention is a plurality of transmission passages 450 formed in the rotating part 330 . ) is changed according to the number of

The formation angle means an angle formed between the processing supply passage 441 and the preliminary supply passage 442 about the indexing axis C as shown in FIG. 6 .

For example, the number of the delivery passages 450 is equal to or greater than the number of the supply passages as described above. When the number of the delivery passages 450 is two, the formation angle is 180°, and the When the number of transmission passages is 3, the formation angle is 120°, when the number of transmission passages is 4, the formation angle is 90°, when the number of transmission passages is 6, the formation angle is 60°, and when the number of transmission passages is 8 The angle of formation is 45°, etc., and the angle of formation is changed according to the number of passengers in the delivery channel.

Referring to FIG. 7 , the arrangement angle between the two adjacent communicating parts 451 about the indexing axis C of the tool cooling device 1 of the machine tool according to the present invention is the processing supply flow path 441 and the preliminary It is formed to have the same angle as the angle formed between the supply passages 442 .

The arrangement angle means an angle formed between two adjacent communication parts 451 about the indexing axis C as shown in FIG. 7 .

For example, when the number of transmission flow paths 450 is two, when the formation angle is 180°, the arrangement angle also has an angle of 180°, and when the number of transmission flow paths 450 is 3, the formation angle is 120°. If made, the arrangement angle will also have an angle of 120 degrees.

When the number of transmission passages is 4, the formation angle and arrangement angle are each 90°, when the number of transmission passages is 6, the formation angle and arrangement angle are each 60°, and when the number of transmission passages is 8, the formation angle and Each arrangement angle has an angle of 45°.

As such, in the tool cooling device of the machine tool according to the present invention, the angle of formation of the processing supply passage and the preliminary supply passage is changed according to the number of transmission passages formed in plurality in the rotating part, and the arrangement between the two adjacent communication parts about the indexing shaft. Since the angle has the same angle as the angle formed between the processing supply passage and the preliminary supply passage, even when the number of delivery passages is expanded, when the turret is indexed, the delivery passage communicates with the supply passage precisely according to the indexing angle of the turret for cooling. Since it is possible to deliver the fluid, cooling of the machining tool and pre-cooling of the standby tool can be implemented accurately enough, so there is an effect of improving the machining precision by preventing erroneous machining due to heat generation in advance.

Four communication parts 451 of the tool cooling device 1 of the machine tool according to the present invention are formed through the rotation part 330 with the indexing axis C as the center to have an arrangement angle of 90 degrees, and the processing supply flow path 441 ) and the preliminary supply passage 442 may be formed through the fixing part 320 so as to have a formation angle of 90 degrees with respect to the indexing axis.

As described above, the cooling fluid may be selectively transferred to the delivery passages by extending the plurality of delivery passages through the two supply passages. However, since a portion of the transmission flow path is formed through the rotating part 330, four transmission flow paths may be preferably formed in consideration of the diameter of the rotating part and the overall size of the machine tool, and in this case, the formation angle and the arrangement angle are 90 degrees. As it is formed, the supply channel and the delivery channel are accurately communicated to deliver the cooling fluid.

In the detailed description of the present invention described above, although it has been described with reference to preferred embodiments of the present invention, those skilled in the art or those having ordinary skill in the art will It will be understood that various modifications and variations of the present invention can be made without departing from the spirit and scope of the present invention. Accordingly, the technical scope of the present invention should not be limited to the contents described in the detailed description of the specification, but should be defined by the claims.

100: tool rest body
200: turret
300: indexing unit
310: casing part
320: fixed part
330: rotating part
340: drive unit
400: cooling unit.
410: cooling fluid supply source.
420: base euro.
430: control unit.
440: supply flow path.
450: delivery euro.

Claims (12)

tool rest body;
a turret on which a plurality of tools are mounted and installed on the tool rest body;
an indexing unit for rotating the turret; and
A cooling unit having a supply passage and a delivery passage and cooling one or more tools mounted on the turret; includes;
When the turret is indexed, the transmission flow path selectively communicates with the supply flow path according to the indexing angle of the turret to cool the machining tool for processing the workpiece with the cooling fluid delivered through the supply flow path and pre-cool the standby tool A tool cooling device for a machine tool, characterized in that.
3. The method of claim 2,
The delivery path is
The tool cooling device of a machine tool, characterized in that formed in a part of the indexing unit so as to be the same number as the supply passages or one or more more than the supply passages.
According to claim 1,
The indexing unit is
a casing part installed on the tool rest body;
a fixing part fixedly installed to the casing part;
a rotating part adjacent to the fixing part and rotatably installed inside the casing part; and
and a driving unit installed on the tool rest body to provide rotational power to the rotating unit.
4. The method of claim 3,
The supply flow is
a processing supply passage formed through a portion of the fixing part to receive a cooling fluid for cooling the processing tool; and
and a pre-supply flow passage formed through a portion of the fixing part to be spaced apart from the machining supply flow passage at a predetermined angle with respect to the indexing shaft in order to pre-cool the preliminary tool.
5. The method of claim 4,
The forming angles of the processing supply passage and the preliminary supply passage are changed according to the number of transmission passages formed in a plurality of the rotating part.
6. The method of claim 5,
Each of the plurality of delivery passages,
a communication part extending through the rotating part so that one side selectively communicates with the processing supply flow path or the preliminary supply flow path according to the indexing angle of the turret; and
In order to cool the machining tool or pre-cool the standby tool, an extension portion is bent from the other side of the communication portion to extend adjacent to the tool mounted on the turret so as to be perpendicular to the indexing axis; The tool cooling system of the machine.
7. The method of claim 6,
A tool cooling apparatus for a machine tool, characterized in that the arrangement angle between the adjacent two communicating parts with respect to the indexing axis is formed to have the same angle as the angle formed between the processing supply passage and the preliminary supply passage.
5. The method of claim 4,
The cooling unit is
a base passage having one end connected to the cooling fluid supply source and the other end connected to the supply passage; and
and a control unit installed on the base flow path to control the supply and blockage of the cooling fluid from the cooling fluid supply source to the supply flow path.
9. The method of claim 8,
The base oil is
a machining base flow path having one side communicating with the cooling fluid supply source and the other side communicating with the machining supply flow path for supplying a cooling fluid for cooling the machining tool; and
and a preliminary base passage communicating with the cooling fluid supply source on one side and communicating with the preliminary supply passage on the other side in order to supply a cooling fluid for pre-cooling the standby tool.
10. The method of claim 9,
The control unit,
a first control unit installed on the processing base flow path to control supply or blockage of the cooling fluid from the cooling fluid supply source to the processing supply flow path; and
and a second control unit installed on the preliminary base flow path to control supply or blockage of the cooling fluid from the cooling fluid supply source to the preliminary supply flow path.
8. The method of claim 7,
Four communicating parts are formed through the rotation part to have a disposition angle of 90 degrees with respect to the indexing shaft,
The tool cooling apparatus for a machine tool, characterized in that the processing supply passage and the preliminary supply passage are formed through the fixing part to have a 90 degree forming angle with respect to the indexing axis.
10. The method of claim 9,
The tool cooling device for a machine tool, characterized in that the first adjustment portion and the second adjustment portion is formed of a solenoid valve.

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