BE1019686A3 - TEST BANK FOR PALLETIZED GOODS. - Google Patents

Abstract

The invention relates to a machine and methods using this machine that are suitable for testing the shape stability of a stack of goods by subjecting that stack to a controlled, horizontal acceleration. The controlled horizontal acceleration can run over time according to a pre-selected curve or can be perfectly constant during a selected period. The machine can be used to test the stability of the stack under the influence of a single gear or under the influence of repeated accelerations in the reciprocating direction.

Description

Test bench for palletized goods

Description

Currently, the stability of, a stack of products, further called cargo unit, typically a pallet of goods, is tested using various types of machines or devices:

With a first device, the pallet with goods is placed on a trolley that can move itself on a sloping surface. The pallet with goods is secured or not on the loading floor of the car, for example with the help of straps. The car is constructed in such a way that the loading floor is horizontal when the car is on the sloping surface. The carriage rolls under the influence of gravity down the slope and collides with a wall. The height of the wall can often be selected such that only the carriage collides with the wall, the carriage and the pallet collide with the wall. the car with the pallet and part of the goods hit the wall. The material that is bumped into can also be selected, ranging from concrete to a certain thickness of polystyrene. Of course, the length of the ramp along which the carriage rolls down can also be selected. This distance determines the collision speed. The described test method can be used, among other things, to check to what extent the transport packaging of a cargo unit of goods is sufficiently robust. If the goods consist of cardboard boxes wrapped as a whole with stretch film, it can be checked to what extent the boxes move relative to each other, to what extent the boxes are released from the pallet, to what extent the lower boxes deform during the collision, ...

In practice, such a device and the associated test method are particularly useful for relative tests: mutual comparison of the stability of different packages, different goods, ... The exact forces and certainly the duration of the force action cannot be set, so that it cannot be determined whether the load unit can withstand a specific force for a specified time.

A second existing group of devices consists of a table on which the pallet with goods can be placed. The table is made to vibrate. Different variants are possible here depending on the installation that generates the vibrations: it can be a purely vertical vibration, a vibration in a vertical plane with identical amplitude and frequency in two orthogonal directions within said vertical plane, a vibration in a vertical plane that is fully adjustable within a certain frequency and amplitude spectrum in two orthogonal directions, a vibration with 3 degrees of freedom to even a vibration with 6 degrees of freedom that can each be adjusted with a certain frequency and amplitude. This type of testing is intended to investigate the influence of vibrations during transport on the stability of a load unit. In this context, there are even various standards that describe which vibrations must be imposed on a load unit. By using such a standard vibration curve, it becomes possible to carry out relative tests again: different packages, different goods, different temperatures, ... can be compared.

With a third existing type of test device, the pallet with goods is placed on a table. It can or cannot be secured on this. The table is then slowly tilted. The angle of inclination of the table at which the load unit becomes unstable is a measure of the stability of the load unit secured or not. Such a test device is very simple and suitable for comparing different load units. Again, it is not possible to unambiguously demonstrate that a load unit can withstand a specific force during a specific time.

It is not possible to predict with the aid of the devices described and the associated test methods whether a load unit, whether or not secured in the loading space of a truck, boat, aircraft or elsewhere, is sufficiently stable to withstand specific inertia forces. However, various regulations, norms or laws prescribe numerical values of acceleration to which a secured load unit must be able to comply.

The machine, called acceleration bench, which is the subject of the invention of this patent, used according to the methods that also form part of this patent, makes it possible to check whether a load unit, secured in a specific way, to the forces resulting from a prescribed can resist acceleration.

This invention relates to a machine for accelerating a loading unit, such as a stack of products, in particular a pallet with goods. The invention also relates to a method for testing the stability of the stacking of the goods, from a method for testing the stability of a possible securing of the goods on a pallet, from a method for testing the stability of the fuse of the pallet in a particular load space, from a method for testing the stability of a load unit placed against a second load unit. For this the load unit is subjected to a controlled horizontal acceleration. The controlled horizontal acceleration can run over time according to a pre-selected curve or can be perfectly constant during a selected period.

A first aspect of the invention relates to a device that comprises a double precision guide on which a carriage can move. The carriage is mounted on the guide with guide blocks that absorb transverse forces and vertical forces. The stator of a specific electric motor is fixed to the carriage. The rotor of the motor is connected with a coupling to a gearbox with an output shaft on which is mounted a gear which in turn engages a gear rack which is attached to the frame on which the guide is also mounted. During assembly, the gear is pushed radially against the rack with a radial force of approximately 5% of the tangential force that a tooth can withstand. The car moves over the guide by rotating the motor. A loading floor is provided on the trolley that can be equipped with various materials, including the materials that are customary for executing loading floors of trucks or the like, such as steel, aluminum chipboard, plywood, anti-slip mats, ... cage must be fitted with numerous securing points for securing aids so that the load unit can be secured on the loading floor as desired or as usual in the transport sector. The machine can be provided with a position-measuring system, either based on measuring the position of the carriage relative to the stationary part, or based on measuring the angular position of the rotor with respect to the stator of the motor.

A preferred embodiment of a device according to the present invention also further comprises at least one movable partition placed against the load unit or at a short distance from the load unit, preferably in the direction of movement of the load unit to be tested. Such a bulkhead can be provided with a coating in the material which is also located on the outside of the load unit to be tested. The bulkhead can tilt backwards during acceleration and returns to a vertical position when decelerating. Both in the acceleration phase of a test and in the deceleration phase, the load unit to be tested and the bulkhead can exert relative movement relative to each other, as is also the case with different load units that are placed one behind the other on a braking truck.

A device according to the present invention preferably comprises the use of a synchronous motor, more particularly a so-called torque motor, which can supply a high torque at low speed, independently of the speed within a certain range. Such a motor allows angular position of the rotor to be achieved as a function of time corresponding to a certain linear acceleration of the carriage as required for the test methods described below.

Preferably, an apparatus according to this invention further comprises the use of a gearbox with a gear ratio between 0.1 and 10, such as in particular 1/1 (no reduction), a toothed toothed gear and a pitch circle circumference of 400 mm. Such a configuration makes it possible to subject a mass of up to 3000 kg, such as in particular 2000 kg, to an acceleration of up to 20 m / s 2, such as in particular 10 m / s 2. A further preferred embodiment of a device according to the present invention achieves a speed of 6 m / s at an engine speed of 1500 rpm.

By controlling the angular position of the rotor of the motor as a function of time, the carriage with a load unit on it can be accelerated exactly as desired in the direction of the guide. A device according to the present invention preferably further comprises a controller for adjusting the desired angular position of the rotor and / or the desired acceleration of the load unit.

A second aspect of this invention includes methods for testing the stability of a load unit that are made possible by using the machine according to the first aspect of this invention.

A first method relates to a method for testing the stability of a stack of goods under the influence of the inertia forces that arise during a certain acceleration. This method comprises: (i) arranging the load unit to be tested, such as a stack of goods, e.g. on a pallet, on the trolley or loading floor of the gear bank, (ii) optionally bringing the trolley with negligible accelerations and speeds to one end of the guide; (iii) causing the carriage to accelerate with the determined acceleration, preferably for a specified time, by driving the electric motor. A preferred embodiment of this method further comprises (iv) stopping the carriage by braking it, which is preferably done slowly.

A second method relates to a method for testing the stability of a secured stack of goods, typically goods stacked on a pallet and secured by means of stretch film, shrink film, strap bands, anti-slip paper, or other means desired or customary in the transport sector, among influence of the inertia forces that arise with a certain acceleration. This method comprises (i) arranging the secured stack of goods on the car or loading floor of the acceleration bench; (ii) optionally preventing the bottom part of the secured stack of goods from shifting relative to the trolley or loading floor, preferably by arranging an interrupted or non-interrupted fender of a few cm height around the trolley; (iii) causing the carriage to accelerate with the determined acceleration, preferably for a specified time, by driving the electric motor. A preferred embodiment of this method further comprises (iv) slowing the carriage to a halt by braking it.

A third method relates to a method for testing the stability of a cargo securing system under the influence of the inertia forces that arise at a certain acceleration. This usually concerns the securing of a load unit on the loading floor of a truck or the like. A load securing system can use straps, chains, supports and walls. For this purpose, a floor plate is preferably first arranged on the trolley of the gear bank, wherein the floor plate consists of the material of the loading floor on which the loading unit is secured. For this purpose, the necessary anchoring points and / or walls must also be provided on the trolley of the gear bank, preferably by arranging a cage on one, two or more sides of the trolley, against or at a certain distance from the load unit depending on the load unit. nature of the fuse to be tested. The anchoring points can be provided in the cage as they are also present in the securing system that must be tested. This method comprises (i) mounting the load unit on the floor plate; (ii) installing the elements of the securing system, such as lashing straps, chains, supports, ... and bulkheads; (iii) causing the carriage to accelerate in accordance with the determined acceleration, preferably for a specified time, by driving the electric motor. A preferred embodiment of this method further comprises (iv) slowing the carriage to a halt by braking it. The force in fuse elements can also be measured during such a test.

A fourth method relates to a method for testing the stability of a load unit, taking into account the influence of a second load unit, which may or may not be identical, placed against or at a short distance from the first load unit. This method comprises (i) placing a bulkhead against or at a short distance for the load unit to be tested, in the direction of movement of the load unit to be tested; (ii) cause the car to accelerate with the determined acceleration, preferably for a specific time, by driving the electric motor. This will cause a bulkhead to tilt against the load unit to be tested. Depending on the stability of the load unit, it will deform more or less away from the direction of movement. The acceleration is preferably maintained for a specific time after which (iii) the carriage is (slowly) slowed down. With the delay, the bulkhead will tilt back to the vertical position and the load unit to be tested will, if it exceeds a certain minimum stability limit, evolve to a vertical position again. Breaking the deformation of the pallet to be tested in the direction of movement is, however, prevented by a baffle which simulates the presence of a second loading unit. Preferably, this movable bulkhead, as described for a preferred embodiment of a device according to the invention, is coated at the rear with foil, cardboard, or another material, namely the material located on the outside of a second loading unit.

The machine and the methods of this invention can be used to test the stability of the stack under the influence of a single acceleration or under the influence of repeated accelerations in the reciprocating direction. The load unit whose stability is being tested can simply be placed on the moving part of the machine to test the stability of the load unit itself. The load unit can also be secured to the moving part of the machine to test the stability of the secured stack.

Thus, an example of a machine according to the invention is built and used to perform tests according to the second and third of the described methods of the invention. For this purpose, the car of the gearbox is provided with a plate consisting of a 40 mm thick wooden plywood that is provided with a glass fiber layer on top, in this case an EcotransGFA® plate. A wooden euro pallet was placed on this loading floor on which 50 boxes of corrugated cardboard were stacked in 5 layers. A layer of anti-slip paper is applied between the pallet and the bottom layer of boxes, as well as between the different layers of boxes. The boxes contain consumables, in this case bottles of detergent. The whole of the pallet and the boxes is wrapped with a stretch film with a thickness of 0.100 mm according to a described winding pattern. This whole is a typical load unit, in this case with a mass of 1450 kg.

For testing the stability of a secured stack according to the second method of the invention, the pallet with the boxes, the anti-slip layers and the stretch film is simply placed in the middle of the carriage on the EcotransGFA® plate. The carriage has been accelerated by 8 m / s2 with the stack of boxes tipped over. From this it is concluded that the secured stacking cannot resist inertial forces as a result of an acceleration of 8 m / s 2.

The stability of a cargo securing system has been tested according to the third method of the invention. On the EcotransGFA® plate a rubber anti-slip mat is placed the size of a euro pallet. In addition to the anti-slip mat, two anchoring points are screwed onto the EcotransGFA®. Between the anchoring points on the anti-slip mat is a wooden pallet with boxes of detergent as described above. The wrapped pallet of goods is clamped down with 1 strap, the strap being attached to the anchor points. The strap is in this case tightened with a force of 3000N. The carriage is then slowly brought to the end of the guide. The motor is then set to achieve an acceleration of 10m / s2 for 0.5s, immediately followed by an acceleration (deceleration) of -5m / s2 to a standstill. After this movement, the load unit was inspected. In this case, no boxes have fallen off the pallet and the pallet has not shifted relative to the carriage. From this it can be concluded that the tested securing system withstands the forces as a result of an acceleration of 10 m / s 2.

However, the invention has a wider application domain than just the tests according to the four methods described. Thanks to the mounting force between the gear and the rack, it is possible to subject a load unit mounted on the carriage to a highly controlled horizontal vibration. For this purpose, it is sufficient for the motor to perform a reciprocating movement with the desired amplitude. It is not only possible to choose the frequency, it is even possible to check the progress of the acceleration within a movement cycle. The force in fuse elements can be measured during such a test.

Claims (11)

A machine suitable for testing the stability of a stack of products, of a load unit, of a load securing system, of a load unit that interacts with an adjacent load unit, comprising a carriage that can move over a: (double precision) guide with a specific acceleration, driven by a specific electric motor, the stator of the motor being fixedly mounted on the carriage, through a gearbox the output shaft of which is provided with a gearwheel which engages a radial pre-tensioning force in a matching rack that is mounted on the same frame on which the guide is also attached: A machine according to the first claim wherein the electric motor is a synchronous motor. A machine according to claim 1 or 2, wherein the gear shifting gear of the gearbox is between 0.1 and 10. A machine according to claims 1 to 3 which is capable of accelerating a mass up to 3000 kg with a gear of choice with a maximum size of 20 m / s 2 to a speed of 10 m / s, the gear box further comprising a housing with only one single bearing. " 5. A machine according to; claims 1 to 4, wherein the carriage further comprises at least one of the following: a loading floor, an abutment, whether or not interrupted, around the carriage or loading floor, a cage j; which is provided with at least one attachment point for securing aids and a baffle, wherein said baffle can be positioned at any location on the carriage and which, when accelerated, can tilt about a horizontal axis and can be covered with a material of choice. ; - A machine according to claims 1 to 5, wherein the machine further comprises a measuring system for the position of the carriage. A method for testing the stability of a stack of goods or load unit under the influence of the inertia forces that arise at a certain horizontal acceleration, comprising (i) applying the load unit to be tested on the trolley of a device according to claims 1 through 6 and (ii) allow the car to accelerate with the determined horizontal acceleration by appropriate driving of the electric motor. A method according to claim 7 wherein the stacking of goods or the cargo unit are secured by means of stretch film, shrink film, strap tapes, anti-slip paper or other means desired or customary in the transport sector. A method for testing a load securing system and its stability under the influence of the inertia forces that arise at a certain horizontal acceleration, comprising (i) applying the load unit to be tested on the carriage or loading floor of an apparatus according to claims 1 to and with 6; (ii) installing the elements of the securing system, such as straps, chains, supports, ... and bulkheads and securing the load unit and (iii) allowing the carriage to accelerate in accordance with the determined acceleration by appropriate driving of the electric motor. A method according to claims 7 to 9, wherein a movable bulkhead is placed against or at a short distance in front of the load unit to be tested in the direction of movement of the load unit to be tested before the carriage is accelerated, whereby the bulkhead, upon acceleration of can tilt the carriage against the load unit. A method according to claims 7 to 10 wherein the carriage with load unit placed thereon is subjected to successive well-defined horizontal accelerations in reciprocating direction by appropriate driving of the electric motor.