The present invention relates to a working machine for making gears.
In the gear manufacturing sector, a known method of making gears consists of machining a set of teeth on a corresponding piece and subsequently grinding the toothed piece. Each gear cutting and grinding process comprises a respective rough machining phase and a finishing phase of the piece.
Generally, the gear cutting or grinding process is performed by a working machine that comprises a piece-holder table mounted so as to rotate about its own longitudinal vertical axis and an operating head, which is provided with at least one tool for machining the piece, and is movable along a guiding device that extends in a direction substantially transversal to the longitudinal axis of the piece-holder table.
Different tools can be used to perform the rough machining and finishing processes in order to increase machine productivity. It is thus possible to optimize each machining process and cut cycle times. In general, more and more often to perform a complete gear cutting process it is becoming necessary to equip a single tool-carrier with several tools that can perform different machining processes in a single position. Normally the number of tools that can be used and their width is limited by the length of the stroke of the operating head.
Nowadays, the need has arisen to produce gears with particularly large nominal diameters for use in special applications, such as, for instance, in the production of wind power generators.
Therefore, the main object of the present invention is to provide a working machine for making gears that is able of machining particularly large pieces.
Moreover, to increase the production capacity of the working machine there are provided at least two working stations, so that while a first piece is machined in a first working station, a corresponding second piece is centered and/or the corresponding piece-holder unit of the second working station is serviced in the second working station in “masked time”.
A tool changing station may also be provided next to at least one of the working stations.
Thus, according to the present invention there is provided a working machine for making gears as claimed in the appended claims.
The present invention will now be described with reference to the accompanying drawings, illustrating a non-limiting embodiment thereof, in which:
With reference to
The frame 2 may ideally be conceived as consisting of a first portion 2A in which there is a first base (BS1) on which the devices to support, clamp and move the pieces to be machined are arranged, and a second portion 2B, in which there is a second base (BS2) on which the devices to support, clamp and move the rough machining and finishing tools suitable to produce the gears (see below) are arranged.
As illustrated in
Each slide 4*, 4** is slidingly coupled to a relative guiding device (not illustrated) arranged beneath the portion 2A of the frame 2 so as to move, with respect to the portion 2A and driven by a known actuating device that is not illustrated, in a straight line in the direction (X1), respectively, (X2) from and towards the second portion 2B of the frame 2. Each slide 4*, 4** supports a relative piece-holder table 5*, 5** which is suitable to support a large, substantially cylindrical piece (not illustrated) on which the gear cutting and grinding operations are to be performed.
Moreover, each piece-holder table 5*, 5** is also arranged so as to rotate (driven by a relative actuating device that is known and is not illustrated) about a relative vertical axis (a*), (a**), in a respective direction (C1), (C2) so that the machine 1 can machine one tooth of the gear at a time.
Each axis (a*), (a**) is transversal to the respective direction (X1), (X2).
Moreover, each slide 4*, 4** is suitable to be locked with respect to the part 2A of the frame 2 by a corresponding locking device that is not illustrated.
With reference to
A relative slide 8*, 8** is slidingly coupled to each vertical column 7*, 7** so as to move along the vertical column 7*, 7**, driven by a known actuating device that is not illustrated, in a straight line in a respective direction transversal, respectively, to the direction (X1), or to the direction (X2).
Each operating unit 6*, 6** comprises, in turn, a relative support arm 9*, 9** which is hinged to the respective slide 8*, 8** so as to rotate, with respect to said corresponding slide 8*, 8** and driven by a known actuating device that is not illustrated, about a respective fulcrum axis (K1), (K2) (
Each support arm 9*, 9** is suitable to support respective auxiliary devices (not illustrated) for machining and/or controlling the piece mounted on the relative piece-holder table 5*, 5**.
The working machine 1 is also provided with a further operating unit 20 which uses the portion 2B of the frame 2.
Said portion 2B comprises, as mentioned previously, the second elongated base (BS2), which is next to the portion 2A and the ends of which protrude from said portion 2A.
The operating unit 20 comprises a first horizontal slide 22, which extends upwards from the second base (BS2), and is slidingly coupled (for example by means of a rail system) to said second base (BS2) so as to move, along the second base (BS2) and driven by a known actuating device that is not illustrated, in a straight line in a direction (Y1).
A second vertical slide 23 is slidingly coupled to the first horizontal slide 22 so as to move, along the horizontal slide 22 and driven by a known actuating device that is not illustrated, in a straight line in a vertical direction (Z) transversal to the direction (Y1). On the second slide 23 there is a pivoting tube 24 which, driven by a known actuating device that is not illustrated, rotates about an axis (W) in a direction (A). The pivoting tube 24 is suitable to be locked by means of a locking assembly (not illustrated) comprising a plurality of locking devices uniformly distributed about the axis (W).
Again with reference to
Lastly, the third slide 25 supports an operating head 30 comprising an electric motor 31, which extends in the direction (Y), and is provided with an output shaft 32 to which at least one tool 33 is keyed for machining said pieces.
During use, the operating head 30 is moved along the second base (BS2) in the direction (Y1) between two working stations (WS1), (WS2), inside each of which the head 30 faces a piece-holder unit 3**, 3* to machine the piece (not illustrated) mounted on the relative piece-holder table 5**, 5*.
As it continues to travel in the direction (Y1) the operating head 30 is able to move completely outside the machining station (WS2) and enter a tool change station (TC).
In the station (TC) the operating head 30 moves into a portion of the second base (BS2) which protrudes with respect to the first base (BS1) so that an operator (not illustrated) can conveniently change the tool 33.
The operation to change the tool 33 in the tool change station (TC) can be performed manually, or by means of a mechanized tool loading/unloading system (not illustrated).
In each of the two working stations (WS1), (WS2), the machine 1 is able to perform two machining processes on each piece (not illustrated) supported by the relative piece-holder table 5** and 5*, i.e.:
The movements and locking of the two piece-holder units 3*, 3** and of the operating head 30 are controlled and monitored by an electronic control unit (CG) (
One of the many advantages of the machine 1 derives from the fact that when the operating head 30 is facing the piece-holder unit 3**, and thus occupies the working station (WS1), the necessary centering operations can be performed on the piece supported by the piece-holder unit 3* in “masked time” also, if necessary, using any control devices (not illustrated) supported by the support arm 9*.
Moreover, when the operating head 30 occupies the working station (WS1), an operator can also service the piece-holder unit 3*, replace the control devices supported by the support arm 9*, etc., in “masked time”.
Clearly, similar advantages are achieved when the operating head 30 occupies the working station (WS2). In this case the piece supported by the piece-holder unit 3** can be centered in “masked time” also, if necessary, using any control devices (not illustrated) supported by the support arm 9**. Moreover, when the operating head 30 occupies the machining station (WS2), an operator can also service the piece-holder unit 3**, replace the control devices supported by the support arm 9**, etc., in “masked time”.
Clearly, the operating head 30 and/or the slides 4*, 4** can be mounted on different combinations of units other than those described above without departing from the scope of the present invention.
In particular, the tool 33A is an insert milling cutter and the tool 33B is a gear hob 33B.
The type of tool 33A or 33B that is used at a certain stage of the process is clearly chosen according to the material used to make the piece being machined, the type of machining process, etc.
When a tool 33A, 33B is active, in that it is machining the piece, the other tool 33B, 33A is inactive, in that it is not working, and must not touch the piece for any reason whatsoever.
The “total working stroke (CTL), necessary to perform the “combined machining process” using more than one tool, is given by the sum of the “longitudinal distance” (LD) (
In other words, the “total working stroke” (CTL) is defined by the sum of the distances between the single tools plus their width.
The “total working stroke” (CTL) is normally obtained by moving the slide 25 in the direction (Y).
Said “total working stroke” (CTL) may be insufficient for machining particularly large pieces, such as the gears used in wind power generators. When there are two tools 33A, 33B on the operating head 30, an insufficient “total working stroke” (CTL) would also result in the phenomenon known as “heeling”, with the tool 33A still on the piece being machined by the tool 33B. In other words, in machines with insufficient “total working strokes” (CTL), when machining pieces with a large diameter one of the two tools, for example the tool 33A, would not be able to move completely away from said piece when it is being machined by the tool 33B; the tool 33A would therefore clearly damage the piece. The same would happen with the tool 33A working when the tool 33B ought not to be working.
In this case the particular layout of the machine 1 illustrated in
The elongation of the “total working stroke” (CTL) of the operating unit 20 is a significant advantage offered by the layout of the machine 1 illustrated in
The main advantage of the working machine according to the invention essentially consists of the significant elongation of the “total working stroke” (CTL) in order to machine pieces with particularly large diameters, and also to prevent the phenomenon known as “heeling” when the operating head supports more than one tool.
Number | Date | Country | Kind |
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BO2009A 000478 | Jul 2009 | IT | national |
This application is the national stage entry of International Appl. No. PCT/IB2010/001763, which claims priority to Italian Patent Application No. BO2009A
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/IB2010/001763 | 7/21/2010 | WO | 00 | 4/6/2012 |