Cable drum for supplying energy to an electrically powered utility vehicle

Abstract

A cable drum for supplying power to an electrically powered utility vehicle, with an axially running winding body which can be set in rotation about a rotational axis in order to wind up and unwind an electrical cable, wherein on an inside, the winding body carries a plurality of fans which are configured to generate a cooling air stream directed radially outward with respect to a cylindrical drum wall.

Claims

1. A cable drum for supplying power to an electrically powered utility vehicle, with an axially running winding body which can be set in rotation about a rotational axis in order to wind up and unwind an electrical cable, wherein on an inside, the winding body carries a plurality of fans which are configured to generate a cooling air stream directed radially outward with respect to a cylindrical drum wall, wherein the fans are attached to the inside of the winding body by means of a carrier plate, wherein the cooling air stream is conducted to a respective air outlet opening in the cylindrical drum wall via an air guide running between the carrier plate and the inside.

2. The cable drum as claimed in claim 1, wherein in the region of the outlet opening, a separating means is provided, by means of which adjacent windings of a cable wound onto the winding body are held spaced apart in layers in order to form an air passage region.

3. The cable drum as claimed in claim 2, wherein the separating means comprises rods arranged along an outer circumference of the winding body and/or a protrusion running along an outer circumference of the winding body.

Description

BRIEF DESCRIPTION OF THE DRAWINGS

(1) FIG. 1 is a perspective view of an exemplary embodiment of the cable drum according to the disclosure.

(2) FIG. 2 is a sectional depiction of the cable drum shown in FIG. 1 with a separating means according to a first embodiment.

(3) FIG. 3 is a sectional depiction of the cable drum shown in FIG. 1 with a separating means according to a second embodiment.

(4) Before any embodiments are explained in detail, it is to be understood that the disclosure is not limited in its application to the details of construction and the arrangement of components set forth in the following description or illustrated in the following drawings. The disclosure is capable of other embodiments and of being practiced or of being carried out in various ways. Further embodiments of the invention may include any combination of features from one or more dependent claims, and such features may be incorporated, collectively or separately, into any independent claim.

DETAILED DESCRIPTION

(5) FIG. 1 shows a perspective view of an exemplary embodiment of the cable drum according to the disclosure for supplying energy to an electrically powered utility vehicle. In particular, the cable drum is part of an arrangement as described in DE 10 2018 212 150 A1 for the case of a utility vehicle configured as a field chopper.

(6) The cable drum 10 comprises an axially running winding body 12 which can be set in rotation about a rotational axis 16 in order to wind up and unwind an electrical cable 14. For this, the winding body 12 is connected to an electric motor drive (not shown) of the utility vehicle. Left and right terminating flanges 18, 20 form the axial limit of the winding body 12.

(7) The cable 14 serves primarily to supply power to the utility vehicle and comprises a plurality of individual cores consisting of copper, which run mutually insulated in a protective outer sheathing 22. In addition, the cable 14 may serve for electrical and/or optical data transmission. In such a case, the cable 14 comprises further cores in the form of corresponding data and/or control lines. Optical data transmission takes place by means of plastic-sheathed waveguides.

(8) As evident from FIG. 1, on an inside 24, the winding body 12 carries a plurality of fans 26 which are configured to generate a cooling air stream 30 directed radially outward with respect to a cylindrical drum wall 28. More precisely, the fans 26 generate a forced air stream which directly hits the windings 32 of the cable 14 wound onto the winding body 12. Openings 34 formed on the left and right terminating flanges 18, 20 allow air to be drawn in from the environment.

(9) The fans 26 are in the present case electrically driven axial fans, wherein these are supplied with power from the outside via sliding contacts 36 arranged in the region of a rotatable suspension 38 of the winding body 12.

(10) For example, the fans 26 are arranged in rows along the rotational axis 16 of the winding body 12. Several rows of fans 26 are distributed along an inner circumference 40 of the cylindrical drum wall 28. In this way, the windings 32 of a cable 14 wound onto the winding body 12 can be exposed to the cooling air stream 30 over a broad area. The fans 26 are in particular arranged such that their air outlet direction points radially outward with respect to the cylindrical drum wall 28.

(11) According to FIG. 2 and FIG. 3, the fans 26 are attached to the inside 24 of the winding body 12 by means of a carrier plate 42, wherein the cooling air stream 30 is conducted to a respective air outlet opening 46 in the drum wall 28 via an air guide 44 running between the carrier plate 42 and the inside 24. Thus the cooling air stream 30 generated by means of a single fan 26 is divided over several adjacent air outlet openings 46. The carrier plate 42 and air guide 44 may be produced for example as an integral plastic injection-molding. The assembly thus formed is then connected air-tightly to the cylindrical drum wall 28 on the inside 24 of the winding body 12.

(12) The rotation speed of the fans 26 is adapted according to the degree of winding of the cable drum 10. Thus the amount of waste heat to be dissipated naturally diminishes with a decreasing number of superposed cable layers. The cable length unwound or that remaining on the winding body 12 is determined by means of a rotary encoder 48 connected to the rotational axis 16. For this, the number of revolutions detected by the rotational encoder 48 and the direction of rotation of the winding body 12 are evaluated. In addition, the electrical power transmitted via the cable 14 is taken into account on the basis of measurement of current intensity by sensors. The rotation speed of the fans 26, and hence the amount of air supplied, is reduced with a decreasing number of cable layers or diminishing current intensity.

(13) In order to allow as unhindered a dissipation of the waste heat as possible, in the region of each of the outlet openings 46, a separating means 50 is arranged by means of which adjacent windings 32 of a cable 14 wound onto the winding body 12 are held spaced apart in layers in order to form an air passage region 52.

(14) The separating means 50 may be implemented in widely varying fashions. Possible embodiments are shown in FIG. 2 and FIG. 3.

(15) In the case of a first embodiment of the separating means 50 shown in FIG. 2, this comprises rods 56 arranged along an outer circumference 54 of the winding body 12. The rods 56 consist of steel with a plastic coating applied to protect the cable 14.

(16) The air outlet openings 46 are situated below a respective clearance 58 formed by the rods 56. The emerging cooling air stream 30 may thus pass unhindered along the windings 32 of the cable 14 wound onto the winding body 12, and thus carry the accumulated waste heat towards the outside.

(17) Alternatively, in the case of a second embodiment of the separating means 50 shown in FIG. 3, this comprises a protrusion 60 running along an outer circumference 54 of the winding body 12. The protrusion 60 takes the form of a helical ridge 62 which is molded integrally onto the drum wall 28 of the winding body 12. The ridge 62 is interrupted in the region of the air outlet openings 46 so as not to hinder a passage of the cooling air stream 30.

(18) Various features are set forth in the following claims.