WO2005115666A9

WO2005115666A9 - Rotating spindle tool

Info

Publication number: WO2005115666A9
Application number: PCT/DE2005/000977
Authority: WO
Filing date: 2005-05-27
Publication date: 2006-04-20

Abstract

The invention relates to a rotating spindle tool (1) comprising a spindle part that contains a cooling lubricant channel (8) running axially through said part and a cutting head (4) comprising blades and grooves (6). The cutting head has a groove exit region (7) that is axially connected to the spindle part, the grooves (6) of said groove exit region (7) opening into the cooling lubricant channel (8). According to the invention, the cooling lubricant channel (8) comprises a cross-section that remains essentially constant up to the grooves (6).

Description

"Rotating Shank Tool"

The invention relates to a rotary shaft tool according to the preamble of claim 1.

State of the art

From the German patent application DE-A-195 44 556 a rotating shaft tool is known, which comprises a shaft in which a longitudinally extending main channel for coolant / lubricant is provided. Furthermore, the shaft tool has a cutting head connected to the shaft, which has flutes and a groove outlet region, with a sleeve extending between the groove outlet region and the shaft. The sleeve covers a supply channel formed between the main channel and the Nutenauslaufbereich, wherein the feed channel is provided substantially axially parallel to the longitudinal central axis of the shaft and the cutting head having a paragraph-free transition from the main channel to the feed channel and the feed channel to the Nutenauslaufbereich.

Through this approach, a streamlined cooling / lubricants supply can be realized, both a conventional cooling lubrication as well as a

Minimal quantity lubrication possible. In addition, a high strength can be realized even with smaller diameter of the shank tools.

Another document in which the problem of effective supply of coolant / lubricant in flutes of a cutting head is discussed is DE-A-101 21 986.

Herein, a Mehrschneidenreibahle is disclosed, which consists of a shaft portion with a running at its interior, in the axial direction of the channel for cooling lubricant and an axially connected to the shaft part, the tool cutting edges and the flutes cutting head, wherein the cutting part and the cutting head by means of a bore and Pins formed frictionally acting plug-in connection are interconnected. The pin of the plug-in connection is formed as a cylindrical fitting pin on the cutting part, while the associated bore is formed as a fitting bore in the shaft part. The cutting part with flutes extends over the entire journal length. In the rear region of the bore in the mouth region of the shaft part extending through Kühlsσhmiermittelbohrung a franking is formed. The plug-in connection is produced by a shrinkage effected essentially by the shaft part.

Purpose and advantages of the invention

The invention has for its object to provide a rotary shaft tool according to the preamble of claim 1, wherein the cooling lubricant supply to cutting or flutes of a cutting head is further improved.

This object is solved by the features of claim 1, In the dependent claims advantageous and expedient developments of the invention are given.

The invention is based on a shaft tool which comprises a shaft part with a coolant lubricant channel running axially through the shaft part and a cutting head with cutting edges and flutes, which has a flute outlet region which is connected axially aligned with the shaft part. Preferably, the Spannutenauslaufbereich is arranged in a matching bore in the shaft part, for example as a fitting pin and fitting hole. For example, the shaft part is shrunk with bore on the Nutenauslaufbereich. Furthermore, the flutes of the flute outlet region open into the lubricant channel. The core of the invention lies in the fact that the coolant lubricant channel has a substantially constant flow cross section up to the flutes. As a result of this measure, an optimized coolant / lubricant supply is provided, in particular in the case of a minimum quantity lubrication (MQL). The procedure according to the invention is based on the finding that coolant lubricant supplies, which have different channel cross-sections from a rear end of the main channel to a groove outlet region of the cutting head, exhibit comparatively strong turbulences of the coolant lubricant. Because as a result of different cooling channel cross sections, fine oil droplets impinge on enlarged or reduced transition sections, with the result that the deflected coolant lubricant components strike lubricant portions which are not deflected in the direction of flow, which produces turbulence.

Minimal quantity lubrication takes place regularly at an air pressure of 4 to 6 bar and an oil admixture per tool of 15 ml / is 60 ml / h, in particular 20 ml / h to 50 ml / h. By a substantially constant flow cross-section, speed components in the transverse direction are reduced due to the reduction of turbulence conditions, whereby the flow velocity increases. As a result, an increase in the coolant / lubricant throughput is achieved, resulting in an overall more effective cooling / lubrication in the cutting head area.

In a preferred embodiment of the invention, the outer boundary of the coolant lubricant channel widens in a transition section or sleeve region in the vicinity of the flute outlet region in the direction of the flutes. This makes it possible to achieve a paragraph-free adaptation of the flow cross section. In a preferred embodiment, the flute outlet region is formed in the transition section or adapted to the shaft part such that the channel section forming thereby maintains a substantially constant flow cross section.

In a particularly preferred embodiment of the invention, the transition section of the coolant channel has a conical geometry. This can be produced comparatively easily. However, also conceivable round spherical shell-like forms of coolant lubricant channel.

In a further advantageous embodiment of the invention, the cross section of the flutes in the flute outlet region is tuned to the cooling channel cross section. For example, the sum of all flute cross sections may at least partially correspond to the flow cross section of the cooling channel. This will continue a constant flow cross section in the flute outlet area. In a further preferred embodiment of the invention, the transition section of the cooling channel is provided in a tapered portion of the shaft part. In this context, it is also advantageous if the tapered portion of the shaft portion has a smaller diameter than the diameter of the cutting head. Thus, undisturbed machining can also be carried out in comparatively deep holes.

Several embodiments of the invention are illustrated in the drawings and explained in more detail below, indicating further advantages and details.

Show it:

1 shows a reamer in a side view,

FIG. 2 shows the reamer from FIG. 1 in an end view;

FIG. 3 shows an axial section according to the section line B-B in FIG. 2,

FIG. 4 shows a radial section along the section line C - C in FIG. 3,

FIG. 5 shows a side view of a further reamer,

Figure 6 is an axial section of the reamer after

Figure 5 along the section line A-A in Figure 5 and

FIG. 7 shows a radial section along the section line BB in FIG. 6. Description of the embodiments

FIG. 5 shows a first reamer 1 which comprises a shank 2 with a sleeve 3 in which a cutting head 4 is formed. An end portion 5 of the shank 2 is adapted to be received in a conventional chuck of a machine tool.

The cutting head 4 is provided with axially extending cutting edges and corresponding flutes 6 (see in particular FIGS. 2 and 4). Within the sleeve 3, these flutes continue in a Nutauslaufbereich 7, which is surrounded by the sleeve 3, but by a

Diameter reduction in Nutenauslaufbereich 7 in the sleeve 3 with a smaller flute.

The flutes 6 of the Nutenauslaufbereichs open into an axial channel 8 for coolant / lubricant.

For this purpose, in a transition region 9, through which the section C-C in FIG. 3 extends, the axial channel 8 widens in a cone-like manner, whereas an end region 5 of the groove outlet region 7 of the snow head 3 conically projects into the widened region of the axial channel 8. By this procedure, the axial channel 8 can expand up to the grooves 6 of the Nutenauslaufbereichs 8, without changing the flow cross-section of the axial channel 8 to the flutes 6.

As a result, an undisturbed coolant / lubricant flow through the reamer 1 can be formed.

FIG. 5 shows a further embodiment of a reamer 50, which differs from the embodiment according to FIG. 1 in that the flutes 54 and also cutting edges a cutting head 51 with Nutenauslaufbereich 52 not axially, but coiled. An axial channel 53 for coolant / lubricant 53 expands according to the embodiment according to Figures 1 to 4 to the flutes 54 (see Figure 7) also cone-like, with an outer wall 55 of a conical jacket channel 56 formed thereby, for example, an angle α of about 40th Degree and an inner wall 57 of the cone sheath channel 56, for example, an angle ß of about 60 degrees to the axis 58 occupies.

The outer wall 55 of the conical jacket channel 56 is formed in a shaft region 59 and the inner wall 57 of the conical jacket channel 56 through one end of the groove outlet region 52.

With the angular choice of α and ß, it is important to create a constant channel cross section.

Claims

Claims :

A rotating shaft tool (1, 50) having a shaft portion (2) with an axially through the shaft portion (2)

Coolant lubricant channel (8, 53) and a cutting head (4, 51) with cutting edges and flutes (β, 54) having a Spannutenauslaufbereich (7, 52) which is connected to the shaft part (2) axially aligned, wherein flutes ( 6, 54) of the Spannnutenauslaufbereichs (7, 57) in the cooling lubricant channel (8, 53) open, characterized in that the cooling lubricant channel (8, 53) up to the flutes (6, 54) has a substantially constant Störungsquerschnitt.

2. Rotary shaft tool according to claim 1, characterized in that the outer boundary (55) of the coolant lubricant channel in a transition section in the vicinity of the Spannutenauslaufbereichs (7, 52) to the flutes (6, 54) expands.

3. Rotary shaft tool according to one of the preceding claims, characterized in that the

Spannutenauslaufbereich (7, 52) in the transition section (9, 59) is formed so that the thereby forming channel portion (56) has a substantially constant flow cross-section.

4. Rotary shaft tool according to one of the preceding claims, characterized in that the transition section (9) of the cooling lubricant channel (8, 53) has a conical geometry.

5. Rotary shaft tool according to one of the preceding claims, characterized in that the cross section of the flutes (6, 54) in the flute outlet region (7, 52) on the cooling channel cross-section (8, 53) is tuned.

6. Rotary shaft tool according to one of the preceding claims, characterized in that the transition section (9) of the cooling channel (8, 53) in a tapered portion (3, 59) of the shaft part (2) is provided.