Arrangement for cooling heat-treated wires

Abstract

An arrangement for cooling heat-treated wires comprises at least one cooling nozzle, which directs cooling fluid in a direction opposite to the travel direction of the wire, which along with the corresponding coolant channels are embodied in the form of perforations disposed in a planar parallelepiped, forming a central section. Side plates are arranged at both sides to laterally enclose the perforations. Coolant can be introduced into and extracted from the channels through apertures drilled in the side plates. A nozzle directing a separate fluid channel in the direction of wire travel can be embodied in the central region for pre-cooling of wires having a fluid coating.

Description

BACKGROUND OF THE INVENTION

1. Field of the Invention

The invention relates generally to an arrangement for cooling heat-treated wires, and more particularly wherein such wires are cooled by a stream of coolant exiting form a nozzle.

2. Background Art

An arrangement is known from DE 100 58 369 C1 for cooling heat-treated wires. It contains a cooling nozzle that is penetrated by a wire bearing channel, whereby a coolant is supplied to the cooling nozzle via a lateral supply channel, and whereby the coolant runs through a tapering coolant channel in the nozzle and exits the nozzle in the form of a stream, which is directed obliquely toward the wire and against the running direction thereof, and is then drained off through a lateral drainage channel.

It is also known from DE 24 34 109 A1 that the wire can be led through two conical nozzles of which the first directs a coolant onto the wire in the running direction thereof, whereas the second operates in the form of a counter-current nozzle, i.e., it allows the coolant stream to flow toward the wire and against the running direction thereof. A wire cooling device which operates in accordance with this co-current and counter-current principle is also known from DE-AS 1 602 356.

The problem that forms the basis of the invention is to create a cooling device which is especially suitable for cooling flattened wires, whereby this cooling device provides good cooling efficiency even in the case of a compact structure, and it can be manufactured in a problem-free manner, and installed simply, and operated with ease.

SUMMARY OF THE INVENTION

This problem is solved by the characterizing features that include the coolant is supplied to the cooling nozzle via a lateral supply channel, and whereby the coolant runs through a tapering coolant channel in the nozzle and exits from the nozzle in the form of a stream, which is directed obliquely toward the wire and against the running direction thereof, and a nozzle element being in the form of a longitudinally extended parallelepiped, in which, from one longitudinal side, a wire bearing channel and the nozzle together with the coolant supply and drainage channels are incorporated, and openings for the supply and removal of the coolant are cut through, and including a cover plate that is joined to the longitudinal side of the nozzle element and that is capable of being taken off in order to insert the wire.

The construction in accordance with the present invention provides for the configuration of all essential parts, such as the nozzles, the wire bearing channel and the coolant channels, in one single relatively flat parallelepiped-shaped part, whereby they are incorporated therein from one side, or they are preferably configured in the form of apertures in this flat part, and whereby a wire erosion process is especially suitable for this purpose. However, cutting out by means of a laser beam would also be conceivable. Plates, of which one is provided with openings for supplying and removing the coolant, can be joined to both sides of this flat part, whereby these apertures lead to appropriate recesses in the parallelepiped part, and are expediently provided with connecting screw threads for the coolant hoses, whereas the other plate can merely be a cover plate that can be configured in a way such that it can be taken off in order to insert the wire, e.g., using a suitable sealing device.

It is practical in this regard that the supply and removal of the coolant take place from one side—e.g., from the rear, whereas the wire is inserted from the front—without the hoses being interfered with during handling. Alternatively, however, the supply and removal lines for the coolant can also proceed in the form of drilled out holes that are directed upward and downward in the nozzle element and that open out into appropriate channels in the interior of the nozzle element so that the connecting hoses are connected from above or below, but not from the rear. The directions are altered correspondingly in the case of a different orientation (rotation of the entire arrangement through 90°).

In the interests of uniform cooling action on a flattened wire, the supply of coolant to the wire expediently takes place from both sides and over the full breadth thereof. An appropriate double nozzle contains two coolant channels for this purpose, whereby these are tapered in order to increase the flow velocity in the direction of the wire and they lead obliquely to it, so that the two coolant streams impinge on the wire at a small angle. In order to achieve an adequate coolant flow in the case of a compact structure, double coolant supply channels are provided on each side in accordance with the invention, whereby these are fed in parallel and open out, in each case, into a communal chamber, whereby these channels continue in the form of tapering channels that are directed obliquely onto the wire. Correspondingly, two channels are also provided in each case in order to remove the coolant, whereby these channels proceed to the outside from a coolant collection chamber through which the wire bearing channel is led.

In order to seal off the wire bearing channel at the inlet and outlet locations of the wire, hydraulic retarders are expediently provided in the vicinity of these locations, whereby flow eddies are produced in the region of these hydraulic retarders and these reduce the pressure at the introduction and removal locations of the wire in order to counter leaks there. Moreover, additional drainage channels can also be provided—in the form of pressure-relieving “overflows”—between these hydraulic retarders and the ends of the cooling device.

A special form of embodiment of the invention comprises the upstream serial connection of a co-current nozzle, in the form of a pre-cooling nozzle, to the nozzle which operates in the counter-current mode for guiding the wire, whereby, in the case of coated wires, e.g., tin-plated wires, this is to prevent the coating which is still liquid from the heat treatment from being allowed to undulate by the coolant flow that is being directed in the opposite direction to the wire. The coolant, which is flowing with the wire here, builds up a counterpressure and cools the coating sufficiently such that it solidifies and is no longer deformed by the other nozzle's counterflow that then follows. Such a combination of co-current and counter-current nozzles together with the associated coolant channels can be configured in a problem-free manner in one and the same nozzle element in the case of the invention, especially when this nozzle element is configured with a central part that is bilaterally covered with plates, whereby even complicated aperture patterns can be manufactured relatively simply in this central part. It is also possible to adapt the thickness of this central part to the breadth of the flattened wires that are to be cooled in each case, i.e., to provide central parts of differing breadth in accordance with the breadth of the wire, and then, accordingly, to exchange these central parts, whereby the rearward plate with the hose connections is maintained, and the front cover plate can remain the same as well.

BRIEF DESCRIPTION OF THE DRAWING FIGURES

The invention may now be explained in detail by reference to several embodiment examples, of which the following aspects are shown.

FIG. 1 shows a first embodiment of the invention, with a counter-current nozzle, in the form of a schematic plan view (FIG. 1a) and a schematic cross section (FIG. 1b);

FIG. 2 shows detailed views of another embodiment with co-current and counter-current nozzles, whereby FIGS. 2a and 2b respectively illustrate a plan view and a lateral view of a cover plate, and FIG. 2c illustrates a plan view of the central part with two end pieces, and FIG. 2d illustrates the second cover plate, and FIG. 2e illustrates a plan view of the central part with the recesses.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS

The plan view of a first form of embodiment of the invention in accordance with FIG. 1a shows a relatively narrow central part 2 that flares out in a T-shaped manner at the ends, whereby side plates 4 and 6 are joined to the central part on both sides, and whereby these side plates are closed off by the T-shaped flared regions 8. The indicated screw-threaded elements 10 hold the three parts together. The bilateral end pieces 12 complete the device that can be screwed onto an installation component via drilled-out attachment holes 14.

The wire bearing channel 16, which longitudinally penetrates the central part, can be seen in FIG. 1b, whereby the wire which is not illustrated here runs through the wire bearing channel in the direction of the arrow 18. In this way, the wire runs through a nozzle 20 that permits it to be flushed from all sides with a coolant in a direction that is opposite to the running direction of the wire, that is the direction in which the wire is traveling through the system. The coolant is supplied in the direction of the small arrows via four supply channels 22a,b and 24a,b, of which the two channels 22a and 24a open out into a flat chamber 26a, and the two other channels 22b, 24b open out into an additional flat chamber 26b. These two chambers are located on either side of the wire bearing channel 16, and open out into tapering coolant channels 28a and 28b, respectively, which run obliquely toward the wire bearing channel 16. The flow velocity of the coolant increases as a consequence of such tapering, and this serves to improve the nozzle effect. The wire bearing channel 16 is provided with a hydraulic retarder 30 between the two chambers 26a,b, whereby the hydraulic retarder inhibits leakage on the wire-exiting side of the agent that is flowing through.

The stream of coolant, which flows against the wire travel direction, finally arrives in a collection chamber 32 from which, in each case, two drainage channels 34a, 36a and 34b, 36b lead away toward the two sides, whereby the coolant exits from these drainage channels in the direction of the small arrows. On this side, and following on from the collection chamber 32, the coolant channel 16 also has a hydraulic retarder 38 for sealing-off purposes. Moreover, overflows 40a, b in the form of additional drainage channels are provided as well.

The central part 2 with its different channels and drilled-out holes can be manufactured in a relatively problem-free manner since it is initially freely accessible, and it is only closed off by the bilateral side plates 4 and 6.

FIGS. 2a-2e illustrate a different embodiment of the invention. The coolant supply to, and its removal from, the central part 2 does not take place from top to bottom here as was the case in the first embodiment, but rather from the side or rear, via the side plate 4 that contains appropriate drilled-out holes for this purpose in the form of coolant channels. In addition, two nozzles are provided here of which one operates in the co-current mode and the other in the counter-current mode. As can be seen from FIG. 2e, the arrangement is configured symmetrically here, whereby, since the wire-running direction is in the direction of the arrow 18, the left-hand nozzle operates as a pre-cooling nozzle in the co-current mode, and the right-hand nozzle operates in the counter-current mode, that is, with the and against the travel direction of the wire.

As shown in FIG. 2c, the central part 2 is once again configured in the form of a flat parallelepiped with T-shaped flared out regions 8 at the ends between which the side plates 4 and 6 fit in. For the sake of visual clarity, the screw-threaded elements are not illustrated here.

The arrangement of the individual elements can be seen best of all from FIG. 2e. The wire, which runs through the device, namely within the wire bearing channel 16 and in the direction of the arrow 18, first runs through the co-current nozzle 42 where it is pre-cooled from both sides. The coolant respectively enters the supply channels 23a and 23b through the openings 23c and 23d in the side plate 4, and then it runs through the tapering coolant channels 28a, 28b from which it exits in the running direction of the wire. A hydraulic retarder 30 and overflow channels 40a, 40b are once again provided at the inlet end in order to counter any coolant leakage, whereby these overflow channels communicate with openings 40c, 40d in the side plate 4, and whereby the coolant can be removed from these openings. The pre-cooling that takes place at this nozzle is recommended in the case of coated wires whose coating has not yet solidified as a result of the high temperature of the wire. The stream of coolant, which exits from the nozzle 42 and which is led in the travel direction of the wire, cools the coating sufficiently such that it is no longer deformed by the nozzle 20 during subsequent counter-current cooling.

Here, the structure of the two nozzles and the associated channels is symmetric as each is a mirror image of the other. The coolant enters the bilateral supply channels 22a, 22b through the openings 22c, 22d in the side plate 4, and runs through the coolant channels 28a and 28b, which are once again tapering in form, in order then to flow bilaterally onto the wire, which is arriving in the wire bearing channel 16, in order to cool this wire in the counter-current mode, as in the case of the first embodiment example. In the case of the embodiment example that is illustrated here, only single supply channels are shown for the sake of visual clarity, but double channels can also be provided, just as was the case in the first embodiment example. However, three coolant drainage channels 35a and 35b in each case are drawn on each side, whereby the coolant can exit from these channels via the openings 35c, 35d in the side plate 4, and whereby it can then be recycled back into the circuit. A hydraulic retarder 30 and overflow channels 40a, 40b are also provided at the outlet end of the wire. The form of attachment, which is not shown here, of the individual parts to one another can take place in any appropriate manner so that, for example, the anterior side plate 6 can readily be taken off in order to insert the wire into the central part 2, and then it can be reattached. A suitable rapid acting closure device could be provided here. The attachment of the central part 2 to the side plate 4, at which the coolant connections are provided, could also be configured in such a way that the central part can be exchanged without difficulty, e.g., if central parts of differing thickness are provided for wires of differing breadth.

Claims

1. A device for cooling heat-treated wires, having a cooling nozzle that is penetrated by a wire bearing channel, whereby a coolant is supplied to the cooling nozzle via a lateral supply channel, and whereby the coolant runs through a tapering coolant channel in the nozzle and exits from the nozzle in the form of a stream, the coolant being directed obliquely toward the wire and against the running direction thereof, and being removed via a lateral drainage channel, and further comprising:

a nozzle element, in the form of a longitudinally extended parallelepiped, in which, from one longitudinal side, a wire bearing channel and the nozzles together with the coolant supply and drainage channels, are incorporated, and including openings for the supply and removal of the coolant, and

a cover plate joined to the longitudinal side of the nozzle element and being capable of removal in order to insert the wire in the wire bearing channel.

2. The device in accordance with claim 1, further comprising the nozzle element being formed from a central part, from which the channels and the nozzle are bored out in the form of holes, with an adjoined side plate that contains the openings for the supply and removal of the coolant.

3. The device in accordance with claim 1, wherein the nozzle is configured in the form of a double nozzle running conically from opposite sides toward the wire bearing channel.

4. The device in accordance with claim 3, wherein, in each case, the bilateral coolant channels proceed from a flat inlet chamber, from which on both sides of the wire bearing channel several supply channels, are arranged side by side and are obliquely directed, and open out into the inlet chambers.

5. The device in accordance with claim 3, wherein a collection chamber is provided for the exiting coolant is serially connected upstream of the nozzle, when seen in the running direction of the wire, from which several drainage channels, run obliquely oriented relative thereto, and which lead away from the collection chamber.

6. Device The device in accordance with claim 5, wherein a hydraulic retarder is provided in the wire bearing channel.

7. The device in accordance with claim 6, wherein an additional drainage channel is provided, in each case, between the hydraulic retarder and the wire inlet end, on both sides, of the wire bearing channel.

8. The device in accordance with claim 6 wherein the hydraulic retarder is provided in the region where the wire exits the wire bearing channel.

9. The device in accordance with claim 4 wherein the first nozzle, which operates in the form of a counter-current nozzle, has a second nozzle serially connected to it upstream of the first nozzle, whereby the second nozzle is arranged and oriented to present a mirror-image to the counter-current nozzle, and the drainage channels for the coolant are arranged between the two nozzles and, the associated supply channels are all disposed in the same central part.

10. The device in accordance with claim 9, wherein a hydraulic retarder is arranged in the wire bearing channel between each nozzle and the end of the wire bearing channel.

11. The device in accordance with claim 10, wherein coolant drainage channels are provided on the two sides of the wire bearing channel between the hydraulic retarders and the ends of the central part.

12. The device in accordance with claim 10 wherein the end pieces, which are joined to a wire inlet side and a wire outlet side of the wire bearing channel, each being in the form of flat profile sections that are divided at the openings through which the wire passes.

13. The device in accordance with claim 1 wherein a hydraulic retarder is provided in the region where the wire exits the wire bearing channel.