CZ309545B6 - Machining tool - Google Patents

Abstract

The machining tool consists of a carrier (N), a cutting insert (D) and a cutting insert (D) fixed in the seat (S) of the carrier (N). The carrier (N) has at least one outlet (V) of the cutting fluid directed to the face or the back of the cutting insert (D). Between the seat (S) and the cutting plate (D) is a pad (P) with a distribution (R) of the cutting fluid, the inlet of which connects to the outlet (V) of the cutting fluid from the carrier (N) of the machining tool. The pad (P) has at least two outlets (V') directed to the back of the cutting insert (D) and contains a protrusion (F) from which the outlets (V') emerge.

Description

According to the invention, a machining tool consisting of a cutting insert carrier and a cutting insert fixed in the carrier seat, while the carrier is equipped with at least one cutting fluid outlet directed to the face or the back of the cutting insert.

Current state of the art

When machining most common structural materials with tools with replaceable inserts, it is essential to use cooling/lubrication during the cutting process. The worse the physical and chemical properties of the machined material relative to its machinability, the greater the importance of the effect of cooling, while heat is generated during cutting generally due to the friction of the tool surfaces against the machined material and further plastic deformation at the point of chip formation. Its removal then has a crucial effect on the durability of the tool and on the quality of the machined surface, especially in terms of its integrity. The cooling system has positive effects both in terms of cutting itself, lubrication, cleaning and the like.

The medium, usually a liquid, is supplied under standard or increased pressure, in practice it is referred to as high-pressure cooling, during which there is better penetration of the liquid between the chip and the cutting edge of the tool. It is known from the state of the art to cool a turning tool with a liquid, where one of the possibilities is internal cooling, where the cutting liquid is fed through the spindle or turret of the machine tool through a suitable channel system in the tool to the cutting edges, often through holes in the tooth gaps, through which the process medium is fed directly to the tip of the tool to the cutting edge of the tool, especially the holes in the carrier of the replaceable cutting insert so that it is directed directly to the cutting edge in the place of the cut. Replaceable cutting parts are currently most often in the form of so-called replaceable cutting inserts. The plates have different geometrical characteristics and are usually made of solid material with a hole in the middle used for clamping into the holder. The inserts are most often made of cemented carbides, CBN, PCBN or PCD and are provided with a thin layer. However, other materials are also used, from which the entire plate or only the cutting edge is formed.

The cutting insert can be cooled on its face and/or on its back or at the same time. The cooling of both the forehead and the back is considered to be the most complex alternative, while the execution of the cooling depends on the structural arrangement of the carrier. Solutions are known from the state of the art that implement cooling of the face and the back with the help of additional nozzles that connect to the supply of the cooling medium and are directed to the face or back or to the face and back of the cutting insert at the same time. Such solutions are known, for example, from document CZ 2020594 or EP 2873477 A1. Some designs are based on the documents WO 2012070046 A1, US 20160158855 A1 or CZ 2020-159, where the direction of the cooling liquid is defined by the design of the cutting insert itself, equipped with a system of internal distributions, which lead to the front, back or both the front and back of the cutting insert at the same time. A solution described in EP 2873477 is also known from the state of the art, where the back of the cutting insert is cooled at a point through the outlet of the cutting fluid in a pad located under the cutting insert in the tool carrier, but this solution does not allow effective cooling of the back of the cutting insert due to the distance between the back of the cutting insert and cutting fluid outlet. From the file CZ 34848 U1, a solution is known for a tool for machining, adapted for clamping in a machine tool, containing a cutting insert carrier, at least one cutting insert fixed in the carrier seat and a clamping nozzle for clamping the cutting insert and at the same time for supplying cutting fluid to the cutting insert, while the carrier is provided with a cutting fluid supply containing at least one cutting fluid outlet, where the specified clamping nozzle equipped with at least one channel for supplying cutting fluid to the face of the cutting insert can be attached to the carrier. The tool further includes an additional nozzle that can be attached to the carrier, and in the place for its attachment, the carrier contains a second, lower outlet for the cutting fluid, while the attachable additional nozzle is equipped with at least one channel connected to the lower outlet of the cutting fluid from the carrier and intended for supply

- 1 CZ 309545 B6 cutting fluid on the back of the cutting insert. An additional nozzle can be attached under the seat. The nozzle is equipped with a system of channels and connects to the lower supply. The outlet of the cutting fluid is directed from the channel to the back of the cutting insert. The additional nozzle is replaceable and is attached to the carrier with a screw that passes through the body of the additional nozzle into the hole in the carrier equipped with an internal thread. The channels of the additional nozzle narrow towards the outlets, and in this particular design, the channels are circular in cross-section. The channels are targeted to the points of chip removal of the machined material. Such a solution is difficult to assemble and requires partial operations associated with the creation of, among other things, a contact surface for attaching an additional nozzle to the lower outlet of the cutting fluid distribution.

The essence of the invention

The essence of the invention is a machining tool consisting of a cutting insert carrier, and a cutting insert fixed in the carrier seat, while the carrier is provided with at least one cutting fluid outlet directed to the front or back of the cutting insert, where a washer is incorporated between the seat and the cutting insert, while the pad is equipped with a cutting fluid distribution, the inlet of which connects to the outlet of the cutting fluid from the machining tool carrier, while the pad is equipped with at least two outlets directed to the back of the cutting insert, the pad contains a protrusion from which the outlets facing the back of the cutting insert exit in the form of a joint. The pad is equipped with a protrusion from which the outlet of the cutting fluid opens onto the back of the cutting insert, and this from the shortest possible distance so that the cutting fluid gets as close as possible to the cutting site.

The gap-shaped outlet enables an even, controlled spray of the coolant over the entire length of the cutting edge/edge of the insert. This phenomenon has a major effect especially on inserts with a large edge rounding or on tools working in multiple directions, where by covering the entire length of the used edge we can fundamentally increase the liveliness.

It is also advantageous if the joint has a variable profile. Such a design enables the distribution of the cooling liquid with minimal flow loss to the critical areas of the insert with the required intensity.

Furthermore, it is advantageous if the joint is divided by partitions in order to direct the flow of the cooling liquid to the edges of the insert.

Furthermore, it is advantageous if the cutting fluid distribution outlet in the pad is in the form of at least one geometric shape, the sum of whose internal angles is 180°. Advantages are also provided by the design where the cutting fluid distribution outlet in the pad is in the form of at least one geometric shape, the sum of whose internal angles is 360°. The possibility of producing an output channel in different geometric designs has a fundamental effect on the functionality for different technological uses of the tools and their functionality.

It is advantageous if the distribution of the cutting fluid in the pad narrows towards the outlet, under stable pressure with a decreasing diameter, the fluid acquires a higher kinetic speed and thanks to this, a targeted flow of the cutting fluid for a specific operation with a specific tool is ensured.

It is also advantageous if the distributions of the cutting fluid in the pad are curved, which ensures the required orientation of the direction of the cutting fluid. Due to the gradual curvature, there is no turbulent swirling and the flow towards the outlet is smooth, thus preventing pressure and velocity losses.

Compared to CZ 34848 U1, this solution brings advantages both in terms of material (weight) and production savings associated with the production of the nozzle, as well as with the demanding production of the carrier itself, containing the supply channel opening in the area under the seat of the carrier, where, among other things, the contact surface must be machined due to tight nozzle connection (surface roughness and accuracy). The contact surface between the bed of the cutting insert in the carrier and the cutting tool, between which according to the present invention a washer with an outlet is placed, must be created in both cases. So at least one sub-production operation is eliminated as well

- 2 CZ 309545 B6 installation of the nozzle and adjustment using clamping elements with regard to tightness etc. is not necessary.

Clarification of drawings

Fig. 1 shows a general isometric view of the machining tool, Fig. 2 shows a general isometric view of the machining tool with the marking of the internal distribution of the cutting fluid. Fig. 3 shows a sectional view of the tool, Fig. 4 shows the seat in the tool carrier. Fig. 5 shows a view of the washer including the internal design of the cutting fluid distribution, Fig. 6, Fig. 7, Fig. 8 and Fig. 9 show a variant design of the washers.

Examples of implementation of the invention

The machining tool consists of the carrier N of the cutting insert D, and the cutting insert D, which is fixed in the seat S of the carrier N of the cutting insert. The carrier N is equipped with two cutting fluid outlets V. The upper outlet V connects to the internal distribution of the clamping nozzle U, which is used for clamping the cutting insert D and at the same time for supplying cutting fluid to the cutting insert D. The clamping nozzle U is attached to the carrier with screws. The outlet V from the clamping nozzle U points to the face of the cutting insert D. A washer P is inserted between the seat S and the cutting insert D. Both the cutting insert D and the washer P are provided with two coaxial holes O for their attachment to the seat S of the cutting insert carrier N with screws. The pad P is provided with two distributions R of the cutting fluid, which are curved and surround the holes O for the screws in the pad P. The distributions R of the cutting fluid in the pad P taper towards the outlet V'. One end of the distribution R of the cutting fluid connects to the lower outlet V of the cutting fluid from the carrier N. The outlet V of the cutting fluid passes through the bed L of the cutting insert D. The bed L is located in the seat S of the carrier N. The pad P is equipped with two outlets V' of the distribution R cutting fluids directed to the back of the cutting insert D. These outlets V' exit through the projection F of the pads P.

The cutting fluid passes through the carrier N of the cutting insert through the outlet V from the clamping nozzle U and is directed to the face of the cutting insert and through the outlet V' from the pad P at the same time it is directed to the back of the cutting insert D.

Industrial applicability

The tool described according to the technical solution finds its application mainly in the construction of chip machining tools.

Claims (8)

1. A machining tool consisting of a carrier (N) of a cutting insert (D) and a cutting insert (D) fixed in a seat (S) of the carrier (N), wherein the carrier (N) is provided with at least one outlet (V) of the cutting fluid directed to face or on the back of the cutting insert (D), when a pad (P) is inserted between the seat (S) and the cutting insert (D), while the pad (P) is equipped with a distribution (R) of the cutting fluid, the inlet of which is connected to the outlet (V ) cutting fluid from the carrier (N) of the machining tool, while the pad (P) is provided with at least two outlets (V') directed to the back of the cutting insert (D), characterized by the fact that the pad contains a projection (F) from which the outlets exit (V') pointing to the back of the cutting insert (D). 2. Tool for machining according to claim 1, characterized in that the outlets (V') are in the form of a joint ^(s) . 3. Tool for machining according to claim 2, characterized in that the joint (s) has a variable profile. 4. Tool for machining according to claim 2 or 3, characterized in that the joint (s) is divided by partitions (p). 5. Tool for machining according to claim 2, 3 or 4, characterized in that the shape of the joint (s) is in the form of at least one geometric shape, the sum of its internal angles being 180°. 6. Tool for machining according to claim 2, 3 or 4, characterized in that the shape of the joint (s) is in the form of at least one geometric shape whose sum of internal angles is 360°. 7. Machining tool according to claim 1, 2, 3, 4, 5 or 6, characterized in that the distributions (R) of the cutting fluid in the pad (P) narrow towards the outlet (V'). 8. Tool for machining according to claim 1, 2, 3, 4, 5, 6 or 7, characterized in that the distributions (R) of the cutting fluid in the pad (P) are curved.