TR2022007647A2 - A ROTARY CUTTING TOOL WITH IMPROVED ANTI-SHAFT PERFORMANCE - Google Patents

Abstract

The present invention consists of a handle (11) and a cutting part (12) extending from the handle part (11) to a cutting tip (13), where the cutting part (12) has a cutting length, and with grooves (40) extending along the cutting length. proposes a rotary cutting tool (10) comprising a plurality of separated blades (20,30), where each blade of the plurality of blades has a rake surface (21,31), a clearance surface (22,32) and rake surface (21,31). ) and the clearance surface (22,32), where a plurality of blades (20,30) comprise a first type having a wavy rake surface (21) with a wave pattern (50). It includes the blade (20).

Description

DESCRIPTION A ROTARY WITH IMPROVED ANTI-SCRATCH PERFORMANCE CUTTING TOOL Technical Field of Invention The present invention is a rotary cutter according to the part of claim 1 where the state of the art is explained. It's about the team.

Known Status of the Technique Rotational cutting tools, such as end mills, typically have a shank section and a cutting section. It has a cylindrical configuration. The cutting part is adjacent to the handle part of the cutting part a plurality of helically extending from a first end to the opposite end of the cutting part. Includes built-in cutting blade. One of the purposes of milling operations is to improving its stability. Instability in machining processes, weak surface condition and quality problems, thus reducing efficiency and reducing costs and It increases material waste. The recommended rotary cutting tool is suitable for milling operations. It can be used as a solution to increase stability and improve efficiency.

A version of the known state of the art numbered EP2398615 (51), which is within the technical field of the invention. The spring consists of a handle section and a cutting section that defines the cutting length. discloses a rotary cutting tool with a longitudinal axis.

A state-of-the-art version of the technique numbered US9327353 (52), which is within the technical field of the invention. roughing and semi-machining end mill with serrated and non-serrated cutting teeth is explained.

Brief Description of the Invention An object of the present invention is to provide high stability, which increases efficiency in milling operations. It provides a rotary cutting tool with

The present invention consists of a handle section and a cutting section extending from the handle section to a cutting tip, where the cutting portion has a cutting length, and extending along the cutting length He proposes a rotary cutting tool consisting of a plurality of blades separated by grooves, where A plurality of blades, each blade with a rake surface, a clearance surface and a rake surface It contains a cutting edge formed at the intersection of the cavity surface, where very a wave pattern with a number of blades, a wavelength, and an amplitude It includes a first type of blade with a wavy rake surface. The wavy chip surface is an important There is a wave model in the section. The wave pattern consists of at least one of the first type of blades. It starts at a distance from one's cutting edge. This distance is for two first type blades It may be different. In another embodiment of the present invention, one of the first type of blades The wave pattern starts from the cutting edge. Thus, the production process of the first type of blade is easier. is made. The geometry of the waves can be periodic (e.g. sinusoidal), periodic It may not be present, or it may be a combination of the two. Multiple blades also include a straight It includes at least one second type of blade having a rake surface, wherein the second type of blade is first type It is adjacent to the blade. Therefore, the rotational cutting tool is affected by the changes in spindle speed and natural frequencies. Provides robust performance against changes. Additionally, the production of rotary cutting tool Axial depth of cut performance is increased while cost is reduced.

In one embodiment of the present invention, a plurality of blades are combined with the first type of blades and the second type of blades. and a repeating pattern in which the second type of blade alternates with the first type of blade. It has order. Therefore, the fluctuation range of the pitch angle increases and thus the chatter frequencies are effectively avoided.

In another embodiment of the present invention, the wave pattern has a sinusoidal shape.

Thus, the production of the first type of blade is made easier.

In another embodiment of the present invention, wavelength and amplitude are The type of blade is the same for each first type blade. Another version of the present invention In its configuration, the wavelength and amplitude of at least one first type of blade is It is different from the wavelength and amplitude of the first type of blade. Wave amplitude has a strong influence on the shear dynamic behavior, and each wave amplitude It is effective within a specific shaft speed range. Ability to disrupt the regeneration mechanism due to having higher wave amplitude values, natural frequency and shaft speed Conditions where the ratio between is low results in higher stability limits.

However, due to dimensional limitations, high wave amplitudes are not possible at the mouths. production is prevented. Therefore, these rotary cutting tools are subjected to spindle rotation with natural frequency. They lose their effectiveness when the ratio between cycles is too low. rotary As the tip wavelength of cutting tools increases, the number of delays introduced into the system decreases.

Therefore, the effectiveness of truncated tools decreases and the stability limit is reduced to standard finger pressure. It approaches that of the milling machine. On the other hand, higher wavelengths It provides a wider range of reproducible wave amplitudes in production. Because The wavelength must be chosen small enough to produce the desired wave amplitude.

Brief Description of Figures The attached figures are only those whose advantages have been summarized above compared to the known state of the art. It is given to exemplify the invention, which will be explained in detail below: Figure 1 is a perspective view of the rotary cutting tool in the state of the art.

Figure 2 is a perspective view of the rotary cutting tool according to the present invention.

Figure 3 is a schematic view of the rotary cutting tool.

Figure 4a shows a first type blade and three second type blades according to the present invention. The angular position of each blade along the axial height of the rotary cutting tool It is a graph of an unfolded view of the change.

Figure 4b shows a first type blade and three second type blades according to the present invention. The angular position of each blade along the axial height of the rotary cutting tool It is a schematic view of a 3D view of the change.

Figure 5a shows two first type blades and two second type blades according to the present invention. The angular position of each blade along the axial height of the rotary cutting tool It is a graph of an unfolded view of the change.

Figure 5b shows two first type blades and two second type blades according to the present invention. The angular position of each blade along the axial height of the rotary cutting tool It is a schematic view of a 3D view of the change.

Figure 6 shows two first type blades and two second type blades according to the present invention. It is a graph of the pitch angle changing according to the axial position of the rotary cutting tool.

Figure 7 shows the rotary blade with four first type blades in the state of the art. It is a graph of the pitch angle varying with the axial position of the cutting tool.

Figure 8 shows the recommended rotary cutting tools for milling AL7075 and the known techniques of the technique. These are the stability diagrams for rotary cutting tools.

Figure 9 shows the recommended rotary cutting tools for milling Ti6AL4V and the known techniques of the technique. These are the stability diagrams for rotary cutting tools.

Detailed Description of Figures The present invention consists of a handle part (11) and a blade extending from the handle part (11) to a cutting tip (13). recommends a rotary cutter set (10) containing a cutting part (12). The cutting part (12) is a cutting length and a large number of slots separated by grooves (40) extending along the cutting length. It has blade (20,30). Each blade from a plurality of blades has a rake surface (21,31), a It contains a cutting edge (23,33) formed at the point. Many blades (20,30), wavy It includes a first type blade (20) having a rake surface (21). On wavy metal surface (21) There is a wave model (50). Wave pattern (50), a wavelength (A) and an amplitude It extends helically. The general shape of the cutting part (12), including, but not limited to, It may have a cylindrical shape or a truncated cone shape. Referring to Figure 2, rotary cutting tool (10) The invention is not limited to the number of blades (20, 30) and grooves. It will be appreciated that it can be applied with (40). For example, invention, five blades (20,30) and groove (40), Referring to Figure 3, the chip surface (21,31) of the rotary cutting tool (10) is the chip flow surface. This, rake surface of chips produced due to cutting movement during machining (21,31) It means that it flows over and eventually leaves the cutting zone. Sawdust in Figure 3 angle (60), clearance angle (61) and helix angle (62) are shown. Refer to Figure 2, first type blade (20), a wave pattern (50) having a wavelength (A) and an amplitude (A). It has a wavy rake surface (21). Wave model (50), each wave has a It is defined by a set of waves having a wavelength (A) and an amplitude (A). first type blade (20) wavy rake surface (21), first clearance surface (22) and first cutting edge (23) Contains. A plurality of blades (20, 30) also include at least one second blade with a flat rake surface (31). It includes a type blade (30), where the second type blade (30) is adjacent to the first type blade (20). This Therefore, the step angles between successive blades (20,30) are related to the axis of the rotating cutting tool (10). becomes variable throughout. The second type of blade (30) also includes the second cavity surface (32). and contains the second cutting edge (33). Referring to Figure 2, flat chip surface (31) cutting part (12) It extends helically inside. There is no damage to a significant part of the flat chip surface (31). There is no waveform or any other protrusions or indentations. Available In a preferred embodiment of the invention, the flat rake surface (31) is completely flat and It does not have any waveforms or any other protrusions or indentations.

Referring to Figures 4a and 4b, the rotary cutting tool (10), one first type blade (20) and three The second type contains a blade (30).

According to a preferred embodiment of the present invention, a plurality of blades (20, 30) type blade (20) with second type blade (30) and second type blade (30) with first type blade (20) It has a repetitive pattern that changes alternately. In Figure 2 As can be seen, the rotary cutting tool (10), two first type blades (20) and two second type Contains type blade (30). In this configuration, each first type blade (20) consists of two second type blades (20). It is placed between the blades (30) and each second type blade (30) is placed between two first type blades (20). is placed between them. In this configuration, successive blades (20,30) refer to Figures 5a and 5b The pitch angle between them varies along the cutting length. In Figure 5a, ,1,- the corresponding blade (20,30) corresponds to the wavelength (A) of the jth tooth, A,- of the jth tooth of the corresponding blade (20,30) corresponds to the amplitude (A), P,,- corresponds to the pitch angle of the jth tooth at the corresponding tool height comes from the cutting edge (13) of the wave pattern (50) for at least one of the first type of blades (20). corresponds to the distance from which it started. Therefore, the rotary cutting tool (10) is used for step angles Offers greater fluctuation range. Standard top of the known state of the technique The cut set is shown in Figure 1. Standard truncated tool, type one only It is a rotary cutting tool with blades. As seen in Figure 7, the standard truncated The suit has a fluctuation range between 78 and 96 degrees. Referring to Figure 6, four When two of the blades (20,30) are first type blades (20) and the others are second type blades (20) The fluctuation range is between 72 and 107 degrees. Thanks to this advantage, the system The number of delays introduced increases. As a result, the proposed rotary cutting tool (10) chatter frequencies of the system over a much wider range of shaft speeds and natural frequencies. can prevent. Thus, thanks to the use of the recommended rotary cutting tool (10), this Efficiency in operations increases significantly. In Fig. 8, recommended for milling AL7075 regarding rotary cutting tools and state of the art rotary cutting tools Stability diagrams are given. The wave pattern (50) of the first type of blade (20) is 20 mm It has a wavelength (A) and an amplitude of 1.75 mm. First type blade (20), second type having a large number of blades (20,30) in a repeating pattern alternating with the blade (30) The rotary cutting tool (10) is called the "second embodiment of the invention".

Rotary cutter having one first type blade (20) and three second type blades (30) The tool (10) is called the “first embodiment of the invention”. This rotary cutter tools (10), with standard cutting tool and standard truncated tool are being compared. As can be seen in Figure 8, the second embodiment of the present invention, Best for milling AL7075 (aluminium) at highest spindle speed It has performance. The first embodiment of the present invention, shaft speed between 2500 and 3000 It has the best performance when it is between RPM.

Similarly, the rotary cutter recommended for milling Ti6AL4V (titanium) in Figure 9 stability regarding tools (10) and state-of-the-art rotary cutting tools Diagrams are given. The second embodiment of the present invention is the standard cutting tool and Compared to the standard truncated set. As seen in Figure 9, the current The second embodiment of the invention has the best performance at the highest shaft speed. Shape As can be understood from Figures 8 and 9, while the stability of the rotary cutting tool (10) increases, the rotational The production cost of the cutting tool (10) decreases. Additionally, the recommended rotary cutting tools Thanks to the use of (10), efficiency in milling operations is achieved in a cost-effective manner. It is increased as follows.

In another embodiment of the present invention, the wavelength (A) and amplitude (A) are The first type of blade (20) is the same for each first type of blade (20).

In another embodiment of the present invention, at least one first type of blade (20) is length (A) and amplitude (A) of a first type of blade other than a plurality of first type blades (20) (20) is different from its wavelength (A) and amplitude (A). Thus, the fluctuation range can be increased.

Claims (5)

1. A handle section (11) and a cutting section (12) extending from the handle section (11) to a cutting tip (13), wherein the cutting section (12) has a cutting length, separated by grooves (40) extending along the cutting length It is a rotary cutting tool (10) containing a plurality of blades (20,30), where each blade of the plurality of blades contains a rake surface (21,31), a cutting edge (23,33) formed at one point, where a plurality of blades The blade (20, 30) includes a first type of blade (20) having a wavy rake surface (21) with a wave pattern (50), the feature of the said tool being that a plurality of blades (20, 30) also have a flat rake surface (31). ) and at least one second type of blade (30), where the second type of blade (30) is adjacent to the first type of blade (20). 2. A rotary cutting tool (10) according to claim 1, where a plurality of blades (20, 30), the first type of blade (20) with the second type of blade (30) and the second type of blade (30) with the first type of blade (20). It has a repetitive pattern that changes alternately. 3. A rotary cutting tool (10) according to claim 1 or 2, where the wave pattern (50) is sinusoidal. 4. Rotary cutting tool (10) according to any one of claims 1 to 3, wherein the wavelength (A) and amplitude (A) are the same for each first type of blade (20) out of a plurality of first type of blades (20). 5. A rotary cutting tool (10) according to any one of claims 1 to 3, wherein the wavelength (A) and amplitude (A) of at least one first type of blade (20) are compared to another of a plurality of first type blades (20). It is different from the wavelength (A) and amplitude (A) of the first type of blade (20).