WEFT FEEDER FOR WEAVING LOOMS, INCLUDING AN INDEPENDENT OPTICAL UNIT INTEGRATED INTO THE ELECTROMAGNET GROUP CONTROLLING THE WEFT THREAD RELEASE

Abstract

Weft feeder for weaving looms including a winding group (W) to wind a weft thread on a weft feeder drum (D), an optical unit (P) provided with one or more optical sensors (T, R, S, Z) to monitor the weft thread winding on the drum (D) and its release from said drum, an electromagnet group (E) to control the movement of a stop pin (15) which prevents the weft thread from being released from said drum (D), wherein said electromagnet group (E) is enclosed within a cup-shaped shell (11) from which said stop pin (15) protrudes to interfere with said drum (D), and a weft feeder processing board which controls the logical functions of the weft feeder. The optical group (P) is contained in a protection box (1) and it is electrically connected to said weft feeder processing board by direct wiring (6), and said protection box (1) is housed and removably fixed inside said cup-shaped shell (11).

Claims

1. Weft feeder for weaving looms including a winding group (W) to wind a weft thread on a weft feeder drum (D), an optical unit (P) provided with one or more optical sensors (T, R, S, Z) to monitor the weft thread winding on the drum (D) and its release from said drum, an electromagnet group (E) to control the movement of a stop pin (15) which prevents the weft thread from being released from said drum (D), said electromagnet group (E) being enclosed within a cup-shaped shell (11) from which said stop pin (15) protrudes to interfere with said drum (D), and a weft feeder processing board which controls the logical functions of the weft feeder, wherein said optical unit (P) is contained in a protection box (1) and it is electrically connected to said weft feeder processing board by a direct wiring (6) and wherein said protection box (1) is housed and removably fixed inside said cup-shaped shell (11).

2. The weft feeder for weaving looms according to claim 1, wherein the functions of said optical unit (P) are independent and autonomous with respect to the functions of the electromagnet group (E) enclosed within the same cup-shaped shell (11).

3. The weft feeder for weaving looms according to claim 1, wherein said protection box (1) includes a lower half-box (1a) and an upper half-box (1b) which are mutually joined.

4. The weft feeder for weaving looms according to claim 3, wherein said protection box (1) is dust-and liquid-tight sealed.

5. The weft feeder for weaving looms according to claim 1, wherein said optical unit (P) includes a printed circuit board (2) onto which emitting and receiving optical elements (3) of said optical sensors (T, R, S, Z) are soldered.

6. The weft feeder for weaving looms according to claim 5, wherein said printed circuit board (2) is a rigid-flex printed circuit board including two rigid portions onto which said optical elements (3) are soldered.

7. The weft feeder for weaving looms according to claim 5, wherein darkening elements (5) of foam material are further provided, arranged on said optical elements (3).

8. The weft feeder for weaving looms according to claim 6, wherein said two rigid portions of the printed circuit board (2) have different inclinations and are connected by a flexible portion (2f) of said printed circuit board (2), which contains inside the copper traces interconnecting the components mounted on said two rigid portions.

9. The weft feeder for weaving looms according to claim 5, wherein said wiring includes a wiring cable (6) electrically connected to said printed circuit board (2) and to said weft feeder processing board via plug connections.

10. The weft feeder for weaving looms according to claim 9, further including a rubber gasket (9) sealing an exit hole (8) of the wiring cable (6) coming out of said protection box (1).

11. The weft feeder for weaving looms according to claim 3, further including optical channels (4c) and diaphragms (4d) of said optical sensors (3), which are integrally formed with said protection box (1).

12. The weft feeder for weaving looms according to claim 11, wherein said optical channels (4c) and diaphragms (4d) are respectively formed in said lower half-box (1a) and in said upper half-box (1b).

Description

BRIEF DESCRIPTION OF THE DRAWINGS

[0019] Further features and advantages of the weft feeder provided with an independent optical unit integrated into the electromagnet group which controls the release of the weft thread according to the present invention will however become more evident from the following detailed description of a preferred embodiment of the same, given by mere way of non-limiting example and illustrated in the accompanying drawings, wherein:

[0020] FIG. 1 is an axial sectional view of a weft feeder provided with the independent optical unit of the present invention;

[0021] FIG. 2 is a perspective view of the independent optical unit, before assembly in the cup-shaped shell containing the ELM group;

[0022] FIG. 3 is an exploded view of the optical unit of FIG. 2;

[0023] FIG. 4 is a plan view of the optical unit of FIG. 2, when assembled and fixed into the cup-shaped shell enclosing the ELM group;

[0024] FIG. 5 is a cross-sectional view of the optical unit of FIG. 2, taken along the line V-V of FIG. 4; and

[0025] FIG. 6 is a bottom perspective view of the cup-shaped shell enclosing the ELM group and the optical unit illustrated in FIGS. 2-5.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0026] According to the present invention, in order to solve the above-mentioned problem by means of a constructively innovative solution which is quick and easy to be assembled, tested, maintained and replaced, the independent optical unit comprises a rigid-flex printed circuit board housed inside a closed and sealed protection box, from which only a wiring comes out for connection to a main weft feeder processing board controlling the logical functions of the weft feeder. Said protection box has dimensions and shape which allow it to be stably housed and fixed, by means of removable fixing means, onto the bottom wall of the cup-shaped shell enclosing the electromagnet group E. In said protection box, all the other accessory elements necessary for a correct operation of the optical sensors detecting the weft thread are also pre-printed or inserted, so that the optical unit P according to the invention is a completely autonomous group which has no permanent connection, whether mechanical or electrical, with the ELM group and the relative cup-shaped shell 11 enclosing it, so that it can be quickly and easily removed from the same, for replacement or maintenance operations, by simply loosening the aforementioned removable fixing means, after having disconnected the end plug of the wiring from the weft feeder processing board and freed the wiring from any existing cable glands.

[0027] The innovative construction of the optical unit P of the present invention is clearly visible in FIG. 2 and it is illustrated in greater detail in the exploded view of FIG. 3 and sectional views of FIGS. 4 and 5. Hence, the optical unit P includes a protection box 1 delimiting its external size and comprising of a lower half-box 1a and an upper half-box 1b mutually joined by means of a suitable coupling and closing system which ensures a complete dust-and liquid-tight sealing. The protection box 1 is manufactured by moulding plastic material and contains within all the elements contributing to the operation of the optical unit P. Inside the half-box 1a a rigid-flex PCB 2 is housed, onto which four pairs of emitting-receiving optical elements 3 are soldered (marked in the drawings with the reference number 3 accompanied by a letter index corresponding to the type of sensor: T, S, Z, R). Diaphragms 4d and optical channels 4c serving said optical elements 3 and being necessary for the selection and shielding of the light beams are illustrated in greater detail in FIG. 5, and are formed by moulding, preferably in the same moulding operation as the protection box 1 of which they are therefore an integral part. Each optical sensor of the optical unit P of the present invention, regardless of the control type T, S, Z or R it is intended for, comprises therefore of a pair of emitting-receiving optical elements 3, of respective optical channels 4c and diaphragms 4d, and of darkening elements 5 of foam material which prevent the diffusion of light radiation in undesirable directions. The specific construction and the further details of operation of said optical sensorscharacterised by optical elements 3 of the SMD type mounted with their optical axes parallel to each other and perpendicular to the PCB surface 2are extensively disclosed in the previously mentioned EP-3620561, in the name of the same Applicant, the content of which is herein fully referred to for the sole purpose of understanding the correct operation of said optical sensors, said operation not forming part, however, of the present invention.

[0028] The use of a rigid-flex PCB 2i.e. a PCT comprising of more than one flat and rigid portion of the traditional type, mechanically and elastically connected by portions which are, on the contrary, highly flexibleallows to easily manage the different inclination between the optical sensors of the type S, Z and R, all arranged in a single horizontal plane, and the optical sensor of type T which lies instead on a plane strongly inclined with respect to said common horizontal plane of said first group of sensors. The PCB 2 comprises in fact two distinct rigid portions having different angular orientation, on each of which optical elements 3 of respective optical sensors are soldered, said rigid portions being connected by a flexible portion 2f which contains inside the copper traces interconnecting the SMD components mounted on said two rigid portions of PCB 2.

[0029] In an advantageous manner compared to what disclosed by the above-mentioned prior patent, in the optical unit P of the present invention the optical channels 4c and the diaphragms 4d are directly formed by moulding in the protection box 1; the optical channels 4c being formed in the lower half-box 1a and the diaphragms 4d in the upper half-box 1b, respectively, thus significantly simplifying both the manufacturing and the assembly of this device. In the same half-box 1a, in fact, a precise housing seat for the PCB 2 is preformed, said housing seat comprising of a plurality of elements which cooperate in maintaining the PCB 2 in a predetermined position, so that the PCB 2 insertion into the half-box 1a can be carried out quickly and with the maximum precision of mutual positioning of the optical elements 3 with respect to the optical channels 4c and diaphragms 4d.

[0030] Upon said positioning of the PCB 2 has taken place, darkening elements 5 preferably made of foam material are placed on each pair of optical elements 3. The darkening elements 5 are necessary to prevent an undesirable direct passage of light between the two emittingreceiving optical elements 3 of the same optical sensor, which would compromise the correct operation of said optical sensor. Finally, the PCB 2 is electrically connected to the weft feeder processing board (not illustrated), which controls the logical functions of the weft feeder, by means of a suitable wiring; for example a wiring cable 6 provided with two male terminal connectors, respectively connected on one side to a corresponding female connector 7 integral with the PCB 2, wherein the entire network of the PCB 2 copper traces converges, and on the other side to a special female connector formed in said weft feeder processing board. The wiring cable 6 comes out of the upper half-box 1b through a hole 8 formed in the same, said hole 8 being then closed by a usual rubber gasket 9 which elastically adheres both to the edge of the hole 8 and to the lateral surface of the wiring cable 6, thus ensuring an excellent level of sealing of the optical unit against dust and liquids entering into the protection box 1. Holes formed in the lower half-box 1a, for the passage of the light radiation exchanged by the optical elements 3, are closed and sealed in a manner well known per se by transparent glass discs 10 (FIGS. 5 and 6).

[0031] After having thus completed the positioning of the various components on the lower half-box 1a, the wiring cable 6 is connected onto the same and the upper half-box 1b is concurrently mounted and sealed, by means of an appropriate coupling and closing system which ensures dust-and liquid-tight sealing, thus forming the optical unit P of the invention. At this point, the protection box 1 is installed inside the metal cup-shaped shell 11, which also houses the electromagnet group E, and fixed to the cup-shaped shell itself by means of removable fixing means 13 (for example screws or press studs) housed in through holes 14 provided in the upper half-box 1b. In a manner known per se, the cup-shaped shell 11 can indifferently comprise of a single or multiple elements and is closed at the top by a lid 12 equipped with a sealing gasket. To facilitate and speed up the assembly of the protection box 1 inside the cup-shaped shell 11, its external features of shape and size are designed in such a way as to allow a custom-fit assembly inside the cup-shaped shell 11, while the glass discs 10 partially protruding from the bottom of the lower half-box 1a, as illustrated in FIG. 5, are positioned into respective holes formed in the cup-shaped shell 11 (FIG. 6).

[0032] From the preceding description it is evident how the weft feeder of the present invention has fully achieved the intended objects. The optical unit P described above is in fact completely independent, both mechanically and electrically, from the metal cup-shaped shell 11 within which it is housed, and from the electromagnet group E, and it is therefore possible to quickly remove the optical unit P in its entiretyfor any repair or maintenance needsby simply loosening the removable fixing means 13 and detaching the wiring cable 6 from the weft feeder processing board, upon removal of any cable glands arranged along the wiring cable 6 path. Furthermore, the positioning and wiring of the individual optical sensors 3 are completely independent one the other and therefore, depending on the target weft feeder and the intended use thereof, the optical unit P can be provided with the desired number and type of optical sensors 3, without this requiring any change to the design.

[0033] However, it is understood that the invention should not be considered as limited to the specific arrangements illustrated above, which are only exemplary embodiments thereof, but that different variants are possible, all within the reach of a person of ordinary skill in the art, without thereby departing from the scope of protection of the invention, which is only defined by the following claims.

LIST OF REFERENCES

[0034] Ahollow shaft [0035] Cbase body [0036] Ddrum [0037] Eelectromagnet group (or ELM group) [0038] Poptical unit [0039] Rreserve verification optical sensor [0040] Sexit optical sensor, direction S [0041] Tentry optical sensor [0042] Wwinding group [0043] Zexit optical sensor, direction Z [0044] 1protection box [0045] 1alower half-box [0046] 1bupper half-box [0047] 2rigid-flex PCB [0048] 2fflexible portion of PCB 2 [0049] 3optical elements [0050] 4coptical channels [0051] 4ddiaphragms [0052] 5darkening elements [0053] 6wiring cable [0054] 7female connector [0055] 8housing hole of cable 6 [0056] 9rubber gasket [0057] 10glass [0058] 11cup-shaped shell [0059] 12lid of the cup-shaped shell 11 [0060] 13removable fixing means [0061] 14holes for fixing means 13 [0062] 15stop pin of the weft thread