The present invention concerns a blowing nozzle for supporting a weft thread in a weaving machine, in other words a blowing nozzle for creating a fluid jet for transporting a weft thread along the reed of the weaving machine through the weaving shed.
In the first place is meant by such a blowing nozzle a relay nozzle for an airjet weaving machine, but it is clear that more generally also other blowing nozzles should be understood by it, also for other fluids than air.
It is known that such blowing nozzles can be made in different shapes, as far as the inner shape is concerned as well as the outer shape. The inner shape determines the flow of the fluid leaving the blowing nozzle, in other words of the outgoing fluid jet. Naturally, the aim hereby is for such fluid jet to be as strong as possible and to extend in one particular direction, in order to be able to act as efficiently as possible on a weft thread.
From Belgian patent No. 1,012,608 is known a blowing nozzle for supporting a weft thread of a weaving machine which is provided with a flow-through canalisation for a fluid tracing a bend near the free end of the blowing nozzle to subsequently flow into the environment via an outlet opening, whereby a jet pipe is integrated in this flow-through canalisation in order to improve the efficiency of the outgoing jet. The jet pipe is hereby situated in the part of the flow-through canalisation extending as of the above-mentioned bend up to the outlet opening, which is disadvantageous in that there is little room available for optimizing the jet nozzle. Moreover, the fluid has to be guided through a first narrowing in the bend first, before reaching the critical section of the jet pipe. Due to these successive narrowings, it is not excluded that unwanted turbulences are created.
The present invention aims an improved blowing nozzle with which can be obtained, in general, a more efficient fluid jet and, more in particular, which remedies the above-mentioned disadvantages.
To this end, the invention concerns a blowing nozzle for supporting a weft thread in a weaving machine which is provided with a flow-through canalisation for a fluid tracing a bend near the free end of the blowing nozzle to subsequently flow into the environment via at least one outlet opening, whereby a jet pipe is formed in this flow-through canalisation, characterised in that the above-mentioned jet pipe is integrated in the above-mentioned bend. By integrating the jet pipe in the bend is obtained a more even flow-through. The fluid is hereby simultaneously forced through the bend in a smooth movement and subjected to the jet pipe effect.
Preferably, the flow-through canalisation is made such that it narrows, from before the above-mentioned bend up to the narrowest section of the jet nozzle, in particular the critical section. Thus is obtained that no other narrowings are found before the narrowest section of the jet nozzle which have a negative influence on the jet pipe effect.
The flow-through canalisation is preferably made such that it widens as of the critical section of the above-mentioned jet pipe up to the outlet opening. By this is meant that the opposite walls in this part of the flow-through canalisation move away in relation to each other and/or are parallel to each other at specific locations at the most. Thus, turbulences are avoided in this part, and the jet pipe effect will be optimally transmitted up into the fluid jet leaving the outlet opening.
According to a preferred embodiment, the blowing nozzle is characterised in that the part of the flow-through canalisation extending as of the critical section of the jet pipe up to the outlet opening has one or several of the following characteristics:
According to a particularly preferred characteristic, the narrowing part preceding the critical section of the jet pipe has an upper wall which extends at least with a concave part into the critical section, as opposed to a conventional construction of a jet pipe. Thus, the fluid is optimally bent through the bend to subsequently end up directly in the critical section.
The flow-through canalisation preferably has a rectangular or an almost rectangular section at the jet pipe, jet pipes respectively, as a result of which a uniform jet pipe effect is obtained in the width. This is particularly useful when the lower wall and upper wall are asymmetrical.
Although the above-mentioned characteristics can be combined according to different possibilities, the blowing nozzle according to the invention preferably shows at least the following combination of characteristics in order to maximally optimize the outflow characteristics: that the flow-through canalisation narrows from the part preceding the narrowest section up to this narrowest section of the jet pipe, in particular the critical section; that the flow-through canalisation widens as of the critical section of the above-mentioned jet pipe up to the outlet opening; and that the part of the flow-through canalisation which extends as of the critical section of the jet pipe up to the outlet opening has an upper wall which is made exclusively concave and a lower wall which first has a convex curve as of the critical section and then follows a straight or almost straight curve.
It should be noted that the specific combination of a number of the above-mentioned characteristics of the flow-through canalisation also results in better flow-through characteristics, even when the jet pipe is not situated in the aforesaid bend. According to a second aspect, the invention also concerns a blowing nozzle for supporting a weft thread in a weaving machine which is provided with a flow-through canalisation for a fluid flowing into the environment via at least one outlet opening, whereby a jet pipe is formed in this flow-through canalisation, which thus is not necessarily situated in the above-mentioned bend, characterised in that the flow-through canalisation narrows from the part preceding the narrowest section up to this narrowest section of the jet pipe, in particular the critical section; that the flow-through canalisation widens as of the critical section up to the outlet opening; and that the part of the flow-through canalisation which extends as of the critical section up to the outlet opening has an upper wall which is made exclusively concave, and has a lower wall which first has a convex curve as of the critical section and then a straight or almost straight curve.
Also the above-mentioned fact that the jet pipe is made with a rectangular section is inventive as such. According to a third aspect, the invention also concerns a blowing nozzle for supporting a weft thread in a weaving machine which is provided with a flow-through canalisation for a fluid flowing into the environment via at least one outlet opening, whereby this flow-through canalisation has at least one duct in which is integrated a jet pipe, characterised in that every duct concerned has a rectangular section at least at the height of the accompanying jet pipe.
In order to better explain the characteristics of the invention, the following preferred embodiments are described as an example only without being limitative in any way, with reference to the accompanying drawings, in which:
The device 1 comprises a sley 4 with a reed 5 which is provided with a guide duct 6 through which the weft thread 2 is transported. The weft thread 2 is blown in the guide duct 6 by means of a main nozzle 7 and it is further supported by fluid jets 8, in this case air jets, which are generated via the blowing nozzles 3. As is known, several main nozzles 7-7A can be provided to insert weft threads 2 in the weaving shed as of different weft yarns 9-10.
As represented in
As represented in
The present invention is special in that a jet pipe 21 is formed in the flow-through canalisation 17 which is integrated in the bend 20.
The flow-through canalisation 17 is made as a permanently narrowing part 23 from before the above-mentioned bend 20, more in particular as of the end of the supply part 19 up to the narrowest section of the jet pipe 21, in particular the critical section 22.
The critical section 22 is situated at least partially half-way H1 the blowing nozzle 3 situated opposite to the half H2 in which the outlet opening 18 has been provided, in relation to the longitudinal axis L of the blowing nozzle 3. The critical section 22 hereby forms an angle A with the longitudinal axis L which amounts to at least 15 degrees, and which is preferably situated between 15 and 40 degrees.
The part 24 of the flow-through canalisation 18 which extends as of the critical section 22 up to the outlet opening 18 is made such that it only widens.
The part 24, as represented, moreover shows the following combination of characteristics:
The narrowing part 23 which precedes the critical section 22 has an upper wall 29 which extends at least with a concave part into the critical section 22.
As represented in
By realising the inner walls of the flow-through canalisation 17 as mentioned above, the respective advantages mentioned in the introduction are obtained. More specifically, this design makes it possible for supersonic flow speeds to be developed on the one hand, whereas the creation of shock waves is nevertheless excluded or at least minimised on the other hand.
By supplying fluid under pressure, it is guided, while it is already being forced to trace a bend, into the critical section 22 itself. After the critical section 22 follows an expansion with expansion lines 31, as represented in
It should be noted hereby that no convex part is provided on the upper wall 25, right after the critical section 22. Such a part could allow the fluid to expand, but it would also make the fluid trace a bend in the wrong direction. This disadvantage is avoided, according to a preferred characteristic of the invention, by starting with a concave upper wall 25 right after the critical section 22. Moreover, this concave part can be calculated such that no compression waves or shock waves are generated, which is realised by making sure that the expansion lines 31 evenly fan out as of the critical section 22 into the location of the last expansion line 31A represented in
Thanks to the slight convex part 27, the fluid is bent in the right direction and, thanks to the rectilinear part 28, any further expansions or compressions are prevented after the expansion line 31A, and it is also made sure that the fluid jet 8 leaves the blowing nozzle 3 according to the direction of the part 28, such that a parallel flowing out is obtained.
It is clear that several variants are possible. Thus, for example, several outlet openings 18 can be applied in a single blowing nozzle 3, which are each provided with their own jet pipe 21.
Also, as represented in
Although it is not excluded to provide several outlet openings 18 on top of each other and to each feed them via a jet pipe, it is preferred to use outlet openings 18 which are exclusively provided next to each other such that, per outlet opening 18, the maximum height can be used to build in a jet pipe.
The use of a round section is not excluded. This is for example possible by realising the ducts 30-32 with circular sections, whereby the circles coincide at the top with an upper wall 25, as defined above, and coincide with a lower wall 26 at the bottom, as defined above.
According to a preferred embodiment, the blowing nozzles 3 according to the invention are composed of segments 33 which, as represented in
Such a construction with segments 33 offers the advantage that the inner shape of the ducts 30-32 can be formed very precisely, as the inner sides are easily accessible, as opposed to the case whereby the duct 30 or the ducts 32 have to be provided in a massive body.
Nor is it excluded, as represented in
As represented in
It should be noted that by ‘top wall’ is always meant the wall situated on the outer side of the bend 20, whereas by ‘lower wall’ is meant the side situated on the inside of the bend 20. It is clear, however, that such a blowing nozzle 3 can be applied in different positions in practice, whereby the ‘upper wall’ must not necessarily be situated above the ‘lower wall’.
The present invention is by no means limited to the above-described embodiments given as an example and represented in the accompanying drawings; on the contrary, such a blowing nozzle can be made in different, shapes and dimensions while still remaining within the scope of the invention.
Number | Date | Country | Kind |
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20020740 | Dec 2002 | BE | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
---|---|---|---|---|
PCT/BE03/00221 | 12/16/2003 | WO | 00 | 6/17/2005 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2004/057080 | 7/8/2004 | WO | A |
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Number | Date | Country | |
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20060011253 A1 | Jan 2006 | US |