This invention relates to a core for a roll of material. The material may be printing paper for the printing industry or other material for other industries.
Known cores for rolls of printing paper are traditionally in the form of cardboard tubes. These cardboard tubes have traditionally been thrown away when the roll of paper on the cardboard tube has been used up. However, this represents a significant cost item, and their disposal is wasteful, both in terms of the need to dispose of the cores, and in terms of the need to provide new cores. In addition, in the printing industry, developments in technology have provided reel tracking systems for tracking the rolls of paper as they progress from paper mills to warehouses, docks, customer paper stores, and printing machines. These tracking systems involve tagging the cores with identity tags. The identity tags are also a significant cost item, and users are not satisfied at having to pay for the cost of the identity tags if they are thrown away with the used cores when the printing paper on the cores has been used up.
An attempt to meet the above problem is disclosed in GB-A-2400093 which discloses a core for a roll of printing paper, which core comprises a body portion, a bore through the body portion, a first end member which is removably secured to the first end of the body portion, and a second end member which is removably secured to a second end of the body portion, the core being made of a plastics material. The core disclosed in GB-A-2400093 is a large improvement on the known cardboard cores. However, the core of GB-A-2400093 presents its own problems. More specifically, industry tends to require ever increasing larger rolls of material, in terms of the diameter of the rolls and/or width of the rolls, and also ever increasing speeds of rotation. Beyond a certain size, during use, cores made of cardboard or the plastics material become unstable and prone to breaking. The instability and the breaking provide serious potential hazards for personnel operating machinery, for example printing machinery using up printing paper on a core. The machinery itself can also be damaged. Thus health and safety requirements negate against the use of a core being made of cardboard and also made of a plastics material.
It is an aim of the present invention to reduce the above mentioned problems.
Accordingly, the present invention provides a core for a roll of material, which core comprises a body portion, a first end member which is removably secured to a first end of the body portion, a first bore through the first end member, a second end member which is removably secured to a second end of the body portion, a second bore through the second end member, and a third bore through the body portion, the first, second and third bores all having a common longitudinal axis, the first bore having a smooth inner surface whereby the first bore is able to receive a chuck such that centering of the chuck is facilitated by the smooth inner surface of the first bore, the second bore having a smooth inner surface whereby the second bore is able to receive a chuck such that centering of the chuck is facilitated by the smooth inner surface of the second bore, the body portion being made of a metal, the first and second end members each being made of a plastics material, the first end member having a first flange which abuts against the first end of the body portion, the second end member having a second flange which abuts against the second end of the body portion, the body portion having an uninterrupted outer surface which is such that the first and second ends of the body portion are not reduced in material and strength, the first and second flanges and the body portion all having the same outside diameter such that the core has a continuous rigid non-deformable outer surface for receiving the roll of material, and the core including a radio frequency operable identity tag for enabling tracking of the core in use.
The making of the body portion of a metal helps to overcome the above mentioned instability and breaking problems caused by making the core of cardboard or a plastics material. More specifically, during fast rotational speeds of a roll of material on machinery such for example as printing machinery, the body portion tends to heat up too much if the body portion is made of a plastics material. The result is that the plastics material looses some of its rigidity and then zags so that the body portion no longer extends in a straight line. A core made of cardboard may loose rigidity if subjected to a humid atmosphere. During the rotation, cardboard and plastics material cores tend to become out of balance, with the body portion causing the core to wobble alarmingly and even break. This problem is able to be avoided with a body portion made of metal. The metal does however cause its own problems insofar as the above mentioned use of the identity tags would normally be prevented using a core made entirely of metal. This problem is overcome by having the first and second end members made of the plastics material. The plastics material will normally be chosen such that it is sufficiently soft to give required friction for chucks which are inserted into the first and second members and which are driven in order to cause rotation of the roll of the material. These chucks must not slip in the first and second bores of the first and second end members respectively. Also, the plastics material should not be so hard as to crack during use under cold conditions, for example in countries with cold climates, The retention of the first and the second end members enables the core to be refurbished and not to be thrown away, thereby overcoming the problem of unnecessary wastage that occurs with the cardboard tubes. The use of the metal for the body portion overcomes the problem of having a body portion made of the plastics material or cardboard. The making of the first and second end members in the plastics material overcomes the problem of the metal preventing use of the identity tags. The entire core can be used more than once. After this multiple use, if an end should get damaged, then the end can easily be replaced in order to enable the entire core to carry on being used for further times. The process of the multiple use, repair and further multiple use can be repeated as desired and appropriate.
The core may be one in which the first end member is inserted into the third bore at the first end of the body portion, and in which the second end member is inserted into the third bore at the second end of the body portion. Insertion of the first and second end members into the third bore enables the outside diameter of the body portion to remain the same. If the first and second end members are inserted over the first and second ends of the body portion, then the outside diameter of the body portion becomes increased unless the first and second ends of the body portion are first reduced in diameter.
Preferably, the core is one in which the first end of the body portion receives an insert portion on the first end member, and in which the second end of the body portion receives an insert portion on the second end of the body member.
The core may be one in which the third bore has longitudinally extending splines, and in which the insert portions on the first and second end members have complementary grooves. If desired, the insert portions on the first and second members may be regarded as having the longitudinally extending splines, in which case the third bore will have the complementary grooves. The longitudinally extending splines along the third bore considerably increase the strength of the body portion because the splines increase the wall thickness of the body portion by the depth of the splines. The complementarily engaging splines and grooves hold the first and second end members in place in the third bore and thus rotation applied to the first and second end members by chucks in the first and second bores is able to be transmitted to the body portion and to the roll of material on the core. Usually, the splines will extend the entire length of the third bore. The body portion can then easily be extruded.
In an alternative embodiment of the invention, the core is one in which the third bore is plain, and in which the insert portions of the first and second end members are plain. In this case, the insert portions of the first and second end members may be held in the third bore by an appropriate adhesive, or by other suitable and appropriate fixing means.
In all embodiments of the invention where the insert portions are employed, the first end member may have a first lead-in part, and the second end member may have a second lead-in part. The first and the second lead-in parts enable chucks easily to be inserted into the first and second bores of the first and second end members.
In all embodiments of the invention, the core may include screws which are used in the removable securing of the first and second members to the body portion.
The metal employed for the body portion is preferably aluminium. The aluminium is preferably an aluminium alloy. A presently preferred aluminium alloy is an aluminium magnesium silicon alloy. Such an aluminium magnesium silicon alloy is manufactured under the Trade No. 6063TA and it is used for aircraft structural parts. The use of the aluminium alloy may permit rotational speeds up to three times faster than would be achievable with a body portion made of a plastics material.
The plastics material used for the first and second end members is preferably a polypropylene co-polymer.
The core of the present invention may include an identity tag for enabling tracking of the core in use.
Usually, the identity tag will be provided on one of the first and second members. If desired however the identity tag may be provided on both of the first and second end members. If one of the first and second end members becomes damaged, for example by a chuck, then that damaged end member can easily be replaced, the identity tag retrieved, and the remainder of the core retained.
Preferably, the identity tag is a radio frequency operable identity tag. Other types of identity tag may be employed.
The present invention also extends to a roll of material when including the core of the invention. The material is preferably printing paper but it may alternatively be wallpaper, cardboard, plastics film, foil or fabric. The plastics film may be used in the wrapping industry or the packaging industry. The foil may be made of a plastics material or a metal, for example aluminium. The fabric may be for use as clothing, cloth or curtains.
Embodiments of the invention will now be described solely by way of example and with reference to the accompanying drawings in which:
Referring to
If the core 2 is alternatively made of a plastics material, then a substantial improvement is obtained over the use of cardboard for the core 2. Nevertheless, the demands of the printing industry constantly require larger and larger rolls of paper and greater and greater speeds of rotation of the cores. With rolls of paper having diameters greater than 1.5 meters, and for fast revolutionary speeds, a core 2 made of a plastics material will also tend to become deformed to the shape shown in
Referring now to
The first bore 24, the second bore 29 and the third bore 28 all have a common longitudinal axis. The first bore 24 has a smooth inner surface 30 whereby the first bore 24 is able to receive a chuck 34 such that centering of the chuck 34 is facilitated by the smooth inner surface 32 of the first bore 24. Similarly, the second bore 29 has a smooth inner surface whereby the second bore 29 is able to receive a chuck (not shown) such that centering of this chuck is facilitated by the smooth inner surface of the second bore.
The body portion is made of a metal in the form of an aluminium magnesium silicon alloy which is known in the aircraft structural industry by No. 6063TA. The first and the second end members 22, 26 are made of a plastics material in the form of a polypropylene co-polymer. The polypropylene co-polymer is such that it is sufficiently soft to grip the chucks such that, in use, the chucks in the first and second end members 20, 26 do not turn relative to the first and second end members 20, 26. This is especially important if machinery is used which effects rotational braking through the chucks, thereby producing very high torque levels. The plastics material first and second inserts act as a flexible drive coupling, absorbing sudden or high levels of braking. At such high levels of braking, cardboard would de-laminate. The plastics material is also sufficiently soft that it does not crack during use, especially at cold temperatures. The use of the aluminium alloy for the body portion 18 enables the body portion 18 to be made longer and to support heavier loads during fast rotational speeds of the core 16 than would be the case if the body portion 18 were made of cardboard or a plastics material. If the body portion 18 were to be made of cardboard or a plastics material, then the fast rotational speeds would tend to cause the body portion 18 to bend or break as shown in
The first end member 20 is inserted into the third bore 30 at the first end 22 of the body portion 18. Similarly, the second end member 26 is inserted into the third bore 30 at the second end 28 of the body portion 18. More specifically, the first end 22 of the body portion 18 receives an insert portion 38 on the first end member 20. Similarly, the second end 28 of the body portion 18 receives an insert portion 38 on the second end member 26.
The body portion 18 is such that the third bore 30 has longitudinally extending splines 40. The insert portions 36, 38 on the first and second end members 20, 26 respectively have complementary grooves 42. The splines 40 and the grooves 42 lock together to enable rotation applied to the first and second end members 20, 26 to be applied to the body portion 18. Additionally, as can best be appreciated from
The first end member 22 has a first flange 44 which abuts against the first end 22 of the body portion 18. Similarly, the second end member 26 has a second flange 46 which abuts against the second end 28 of the body portion 18. The body portion 18 has an uninterrupted outer surface which is such that the first and second ends of the body portion are not reduced in material and strength. The first and second flanges 44, 46 and the body portion 18 all have the same outside diameter such that the core 16 has a continuous rigid outer surface for receiving the roll of printing material. Screws 47 may be used for removably securing the first and second end members 22, 26 to the body portion 18.
As shown in
Referring now to
An identity tag 62, which is a radio-frequency identity tag 62, is secured as shown to the outside of the first and/or second end member 20, 26. The identity tag 62 has an antenna 64 which is exposed in the flanges 44, 46 in order to be able to transmit to a control station. The transmission will usually be the transmission of a unique identity number or other appropriate identity. The use of the identity tag or tags 62 enables the roll of paper 60 to be tracked as it passes from a paper mill to a warehouse, a dock, a customer paper store and a printing machine. The identity tags 62 are a significant cost item and they are able to be saved if the first and/or second end members 20, 26 become damaged. Instead of throwing away the entire core 58, the damaged first or second end member 20, 26 can be replaced, and the identity tag 62 retrieved and re-used. The identity tag 62 will usually only be fitted to one of the first and second end members 20, 26. However, with cores over one meter long, or where machinery, logistics or control parameters require it, an identity tag 62 may be fitted to both of the first and second end members 20, 26. If desired, the identity tag can be secured to the body portion 18, for example in the middle of the body portion 18. In this case, two wire antennae may be employed, with one each extending to either end of the body portion 18 and into the end member 20, 26 at that end of the body portion 18. The body portion 18 acts like a Faraday cage and would normally prevent or interfere with signal transmissions. However, because the identity tag 62 has an antenna terminating in one or both of the first and second end members 20, 26, the antenna extends beyond the end of the body portion 18 and signal transmission is able to be achieved.
It is to be appreciated that the embodiments of the invention described above with reference to the accompanying drawings have been given by way of example and that modifications may be effected. Thus, for example, the cores 16, 58 can be used for material other than paper.
Number | Date | Country | Kind |
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0423409.2 | Oct 2004 | GB | national |
Filing Document | Filing Date | Country | Kind | 371c Date |
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PCT/GB2005/003699 | 9/23/2005 | WO | 00 | 11/5/2007 |
Publishing Document | Publishing Date | Country | Kind |
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WO2006/043021 | 4/27/2006 | WO | A |
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