The present invention relates to a stretch film dispenser, and more particularly to an electric stretch film dispenser.
In order to prevent damages to articles caused by shaking or falling during storage or transport, a stretch film dispenser is used for packing the articles. Goods that are transported on pallets must comply with legal requirements of stability. A frequently used method for securing pallet loads is the application of a strong and elastic plastic film. This is done with special machines but almost 50% manually. Here the operator has to exert a great deal of pressure and walk backwards with a bended back while he is pulling on the roll. The harder it pulls, the better is load stability. However, this is completely dependent on the method and physical capabilities and capacities of the operator. It is almost impossible to generate consistent load stability in this way. In practice, it has been shown that approximately 20% elongation (=yield) is effectively applied with the film, while the film reaches its optimum strength around 100% elongation. So 80% of the available stretch is unused in the film without offering load stability of the pallet load.
An additional aspect is that with this long reached value of elongation, the possibilities of the film remain largely untapped and therefore a larger amount of film is required to comply with the law.
A conventional stretch film dispenser comprises a rod. One end of the rod is provided with a film mounting unit. The film mounting unit is provided with a film roll. When the user wants to pack an article, the film of the film roll is first pulled out, and then one end of the film is attached to the surface of the article. The user holds the rod to pull the stretch film dispenser for performing the packing operation.
However, when packing the article, the film needs to be tensioned on the article to be tightly wrapped around the outside of the article. Although the stretch film dispenser is convenient for the user to pack the article, the length of the rod cannot be adjusted. For the article that is located at a higher or lower position, it is inconvenient for the user to apply a force to pack the article, and the tension of the film is reduced. Besides, the stretch film dispenser mounted with a film roll has a certain weight. When the user wants to pack an article that is located at a lower position or when the user wants to move the stretch film dispenser, it is quite laborious.
The present invention is to provide an electric stretch film dispenser. When in use, the electric stretch film dispenser can automatically generate tension, and it can be used to pack articles at different heights. The electric stretch film dispenser can facilitate the application of the film and increase the tension of the film.
In order to achieve the aforesaid object, the present invention provides a dispenser for stretch film, comprising a frame, provided with a film mounting unit and a film dispensing unit, the film dispensing unit comprising a first roller for guiding a film and a second roller for guiding the film, characterized by at least a first drive unit for driving the first and/or the second roller to rotate.
By providing drive for the first or second roller, the dispenser provides an aid for a user that enables to easily apply a film around an article to be wrapped. Preferably, both the first and the second roller are driven. For that aid, one drive may be sufficient, if a mechanic coupling between the first and second roller is provided. Thereto, in an embodiment, the first roller may be connected with a first gear and the second roller may be connected with a second gear, the first gear meshes with the second gear, and the number of teeth of the second gear is greater than the number of teeth of the first gear, and wherein the first and the second roller comprise a surface provided with friction means for providing friction to the film. The gears may be exchangeable, for changing the ratio between the first and the second roller.
The short distance between the second roller and the first roller assures that the stretch foil does not shrink in its width direction. Through the system of film transport between the rollers, which generate a stretch (for instance 75%), a consistent loading ability is achieved. As a result, a thinner and stronger film can be applied. By driving the rollers, the required tensile force is greatly reduced, thereby helping a user to apply the film with a higher force than is possible without this drive.
In another embodiment, a second drive unit may be present, wherein the first drive unit is configured for driving the first roller and the second power drive unit is configured for driving the second drive roller to rotate. Herein it is preferable that the first and the second drive unit are independently controllable, in particular such that the second roller has a rotational speed less than that the first roller.
It is to be understood that a film, mounted on the film mounting unit, is subsequently guided along the second and the first roller respectively. The rotational speed difference between the second and the first roller combined with the friction means serve to stretch the film a predetermined factor, which may be between 10% and 200% percent, and more in particular between 40% and 160%. 120% stretch means that the foil becomes 220% of the length of the initial 100%.
The speed of the first roller and the speed of the second roller may be adjustable in an embodiment, in order to determine the percentage the film is stretched.
The frame may comprise a top seat and a bottom seat, wherein the top seat is provided with a first retaining trough, a first retaining member is fixedly connected to the first retaining trough, and the first power drive unit is connected to the first retaining member, and wherein the bottom seat is provided with a second retaining trough, a second retaining member is fixedly connected to the second retaining trough.
The first drive unit and the second drive unit may be an electric motor, wherein the dispenser comprises a power unit, for powering the first and/or second drive unit. Such power unit may comprise a power storage member, electrically connected to a charging member. Furthermore a control unit may be present, having at least one sensor, the sensor being electrically connected to the first power drive unit and/or the second power drive unit, the sensor being configured to at least turn on/off the first power drive unit and/or the second power drive unit. Such control unit may further have a power switch, the power switch is electrically connected to the power unit, and the power switch is configured to turn on/off the power unit.
The dispenser may further comprise a handle, coupled to the frame, wherein the handle comprises the sensor, and in particular wherein the sensor is operable by pulling the handle with respect to the frame. Such sensor may then be configured for providing a sensing signal that is proportional to the pulling force exerted on the handle, and wherein the controller is configured to adapt the speed of the first and/or second drive in dependency of the sensing signal. The controller may be configured to adapt the speed of the first and/or second drive such that the pulling force is kept at a predetermined value.
The frame of the dispenser may be provided with a clog up prevention unit, said clog-up prevention unit comprising a cover for covering at least part of the surface of at least one roller at at least a side facing away from the film mounting unit. This prevents the film to cling to the rollers once it is dispensed. Hence, there is some kind of physical barrier between the dispensed film and at least one roller which prevents the dispensed film from clinging to the roller and therewith clogging up the dispenser.
As a result, in such embodiment, the device according to the invention has a force-controlled drive whereby the speed of walking through the operator has no influence on the voltage applied around the load. The speed of film feeding is determined by the tensile force that is set on the device. Thus, as it runs faster, the film feeding will also become faster, the stretch on the film remaining consistent. which reduces the amount of plastic, and with that also the CO2 emissions, which may be up to 70%.
In the electric stretch film dispenser provided by the invention, the first power drive unit is actuated to drive the first roller to rotate, and the rotational speeds of the first roller and the second roller are different. When the film of a film roll passes between the first roller and the second roller, the film is pulled due to the difference in the rotational speed, thereby generating tension. Thereby, the electric stretch film dispenser can automatically generate tension when used, so it can be used to pack articles at different heights. The electric stretch film dispenser facilitates the application of the film and increases the tension of the film.
Embodiments of the present invention will now be described, by way of example only, with reference to the accompanying drawings.
The frame 10 has a top seat 11 and a bottom seat 12. The top of the top seat 11 is provided with a socket 13 and a panel 14. The socket 13 is used for the electric stretch film dispenser 100 to be charged. The panel 14 is configured to display the power of the battery, so that the user can pay attention to the use of the device at any time. The bottom seat 12 is provided with a first retaining trough 121. A first retaining member 122 is fixedly connected to the first retaining trough 121. In this embodiment of the present invention, the first retaining member 122 is a retaining shaft. Two ends of the first retaining member 122 each have a noncircular cross-section. The two ends of the first retaining member 122 each may have an elliptical or polygonal cross-section. The top seat 11 and the bottom seat 12 are jointly provided with a film mounting unit 20 and a film dispensing unit 30. The top seat 11 and the bottom seat 12 are provided with a first coupling portion 15 and a second coupling portion 16. A hollow tube 17 is connected between the first coupling portion 15 and the second coupling portion 16. The tube 17 is adapted for the user to hold thereon.
The film mounting unit 20 is configured to mount a film roll 200.
The film dispensing unit 30 includes a first roller 31 and a second roller 32. The first roller 31 and the second roller 32 may be provided with friction means 31A, 31B, 32A, 32B, for instance formed by a rib pattern as shown. The rib pattern has a helix shaped pattern, wherein the orientation is such that the plastic film is moved out from the center, to counteract the tendency of the film to narrow due to the tensile force. The orientation of friction means 31A and 32A may therefore be different from 31B and 32B. This feature can be applied in general, so also without the specific features from this embodiment. As shown in
The power unit 40 is electrically connected to the first power drive unit 33. The power unit 40 includes a power storage member 41. The power storage member 41 is electrically connected to a charging member 42 and the panel 14. In this embodiment of the present invention, the power storage member 41 is a battery. The power storage member 41 is disposed in the tube 17. The charging member 42 serves as the charging socket 13. In other embodiments, the power storage member 41 is a plurality of batteries that can be removed from the tube 17. The charging member 42 may be an independent charger for charging the power storage member 41. In another embodiment, the charging member 42 is a wireless charger.
The control unit 50 has a power switch 51 and at least one start switch 52. In this embodiment of the present invention, the start switch 52 includes a plurality of start switches 521, 522, 523, 524. The power switch 51 is disposed on the top of the top seat 11 and electrically connected to the power unit 40. The power switch 51 is configured to turn on/off the power supply of the power unit 40. The start switch 52 is electrically connected to the first power drive unit 33. The start switches 521, 522 are disposed on the top and the side of the first coupling portion 15, respectively. The start switch 523 is disposed on the side of the second coupling portion 16. The start switch 524 is disposed on the tube 17. In this embodiment of the present invention, the start switch 52 may be a push switch, a touch switch or a wireless switch. The start switch 52 can turn on/off the first power drive unit 33. Alternatively, a force sensor may be present for instance at location 60 or 61, for providing a sensing signal that is proportional to the pulling force exerted on the handle, and wherein the controller is configured to adapt the speed of the first and/or second drive in dependency of the sensing signal.
When an article located at a higher or lower position is to be packed, the user can select an appropriate one of the start switches 521, 522, 523, 524 to actuate and control the electric stretch film dispenser 100 conveniently.
It is to be noted that the first power drive unit 33 is electrically connected to the power unit 40 through the first conductive portion 311. The first conductive portion 311 is a conductive slip ring, which can avoid the problem that the electrical components are wound around each other when the first roller 31 rotates, and can maintain an effective electrical connection.
It is worth mentioning that the power storage member 41 and the charging member 42 may be plug-in, battery-replaceable or wirelessly charged, so that the electric stretch film dispenser 100 can maintain a predetermined usage time and the user can know the remaining electric energy through the panel 14 to prepare for charging.
Although particular embodiments of the present invention have been described in detail for purposes of illustration, various modifications and enhancements may be made.
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