The present invention relates to wheel chocks, and more particularly to a wheel chock restraint system provided to engage the wheel of a truck to prevent it from moving away from the loading dock during loading and unloading.
Loading and unloading operations are hazardous for fork lifts entering and exiting the truck trailer. It is imperative that a truck remain immovably docked to the loading dock to prevent moving fork lifts from falling through the space created if a truck trailer moves truck away from the loading dock during loading and unloading.
There are known two main kinds of restraint systems: ICC bar restraint systems to prevent the truck from moving away from the dock, and wheel restraint systems. However, while the first system is suitable for a majority of trailers, there are several configurations of trucks that cannot be secured by such ICC bars. Besides, ICC bars are built to absorb a rear impact with another truck and are not designed to resist a strong pulling force. In view of this fact, this system does not prevent the truck from moving away from the loading dock. The second category includes manual and mechanical chocks. Manual placement of a chock presents different problems, such as: chocks may be displaced, damaged, lost, or stolen. They also may slip on icy, oily or dusty surfaces and are often difficult to remove from their operational position because they may be wedged very tightly under the trailer's wheel. Very often, chocks are removed before the loading operation is complete, thus creating a dangerous situation where the vehicle can depart prematurely or slide away from the dock as heavy fork lifts enter the trailer. Also, docked trailers can be stolen mostly after business hours. In a lot of cases, targets for theft are trailers loaded with valuables, such as alcohol, beer, cigarettes, or any other goods.
Often, standard chocks are placed too far from the wheel to be effective because they can jam and become very difficult to remove; for example, when an empty trailer becomes heavily loaded, the weight on the tires makes them extend sideways, resulting in the wheel to sit on the chock. A tire can also jam into the chock if the air ride suspension causes a slight movement of the trailer when depressed. Standard chocks are sometimes left lying beside the wheel due to negligence.
Mechanical wheel chock systems are more effective than manual systems. However, they may be buried in the driveway during installations under ground, are expensive to install, require a drainage system to prevent them to be filled with water. They also are not very easy to service and have to travel a substantial distance from storage into operative position. Other mechanical chocks which are mounted on the surface may be affected by winter and become an obstacle during snow removal. They may interfere with the tail gate of the truck or truck's undercarriage, and are inoperable with many types of vehicles.
This invention is related to my Canadian application No. 2,164,738, describing a wheel chock handling system including a movable arm attached by one end to a loading dock and another end to a wheel chock. The arm consists of a front arm and a rear arm. A return spring is attached between the loading dock and the upper end of the rear arm.
The major disadvantage of said system was its effective range: because the spring was attached to the rear arm, the more said arm was extended, the more tension was created in the spring making the handling of said the chock attached to said arm harder and harder after 7 feet of extension of the arm from the loading dock. At the distance of 10 to 14 feet, handling the arm required a great deal of effort and force.
The present invention eliminated these problems and provides an improved system allowing a very easy and effortless way of handling heavy chocks.
The primary object of the present invention is a wheel chock restraint system provided to restrain the movement of a vehicle away from a loading dock during loading and unloading operations. The system comprises a wheel chock having an engagement means adapted to cooperate with a corresponding engagement means of a support plate mounted on the ground. The chock is attached to a movable arm attached to the loading dock and adapted to assure secure positioning of the chock under the wheel of the truck. The arm is provided with a tension means facilitating easy manipulation of the chock and placing the arm into the storage position.
Another object of the present invention is a sensor means provided to detect the wheel and to facilitate proper placement of the chock under the wheel.
Yet another object of the present invention is to provide a wheel chock equipped with a jamming or locking mechanism that will prevent an unauthorized chock removal during loading and unloading or during after business hours. Such jamming mechanism is activated from inside of the building. Jamming mechanism is incorporated within the chock.
Still another object of the present invention is to prevent solid jamming of the chock by means of a locking element keeping a slight distance between the wheel and the chock.
Referring to drawings,
A supporting element 3 is fixed on the ground in the vicinity of the loading dock and comprises an elongated plate long enough to spread at least under one axle of a truck 9 during loading operation to facilitate a proper engagement of a wheel chock 1 with the plate 3. A base portion of the chock 1 is provided with a first engagement means or teeth 2 which are adapted to cooperate with the corresponding second engagement means or stoppers 4 located on plate 3.
Once the vehicle 9 is backed to the dock 27, the truck driver manually sets the chock 1 by means of a handle 35 mounted on the front arm 10 to engage the chock 1 with a wheel 8. The spring 16 attached from the pivot 14 to the upper portion of front arm 10 by means of cable 17 assists the manipulation of the driver of the movable arm A. In this case, on one hand the retention force created by engagement of teeth 2 of chock 1 and stoppers 4 of the plate 3 is directed away from the loading dock 27 and prevents the chock 1 from sliding away from the wheel 8 of the truck 9 when said truck makes attempts to depart prematurely from the dock 27. On the another hand, arm A creates an engagement force directed towards the loading dock 27 and presses chock 1 against the wheel 8. Such a combination of two forces allows to assure a secure positioning of truck 9 during loading and unloading, which is a very advantageous feature of the present invention.
Front arm 10 is pivotally attached to the chock 1 by means of a lower joint 13 and front arm 10 is pivotally connected to rear arm 12 by means of upper joint 11. It should be emphasized that upper joint 11 may be of any possible configurations, such as a universal joint, bracket with a pivot or any other means which facilitates effortless pivoting of both arms. The most important feature of the present embodiment is the fact that spring 16 is attached to the upper portion of the front arm 10. Such arrangement allows very easy manipulation of the system because the more arm A extends, the more spring 16 pulls and consequently chock 1 become lighter and lighter due to the leverage effect. This feature is a substantial improvement over my previous arrangement discussed above wherein spring was attached to the rear arm. However, the present invention is not restricted to use of spring 16 and any other tension means may be used instead to the same purpose.
Pivot 14 is attached to the dock face 27 by means of an anchor plate 15. In the present invention, the engagement means of the chock comprises a plurality of angled teeth 2 extending downwardly from the base portion of the chock 1. Engagement means of the plate 3 comprises a plurality of extending upwardly stoppers 4. However, it must be emphasized that the present invention is not restricted to such an arrangement, and any other possible equivalents may be used instead for the same purpose. In use, chock 1 should be positioned in such a way that teeth 2 should be directed away from the loading dock 27.
Chock restraint system of
Truck presence detector 19 may be installed around the dock to detect a vehicle when arriving in the vicinity of the dock 27. Such detector may also be of contact or non-contact (photocell) arrangement, and is designed to sense the vehicle a few inches from the dock. Using the control panel 24, the vehicle detector 19 can be interlocked with other sensors, such as a restraint sensor 6 or 18 and dock leveller sensor 21. Movement of the truck during loading and unloading operations can trigger a loud alarm 22 to make the truck drivers and fork lift operators aware of danger. Dock leveller detector 21 is installed under the dock leveller 26 and is activated by said dock leveller 21. Loading entrance 27 is also provided with a dock seal 28, dock bumper 29 and interior lights 25 used for the same function as exterior lights 23.
In operation, when the truck backs into position with loading dock 27, wheel 8 rolls over the supporting plate 3. Once the truck 9 is backed up to dock 27, the truck driver will manually set the chock 1 by means of handle 35 mounted on the front arm 10 to engage with the wheel 8. The spring 16 attached from the pivot 14 to the upper portion of the front arm 10 by cable 17 will assist the manipulation of the arm A by the driver to allow easy handling. The dock leveller 26 spans the gap between the bed of the truck 9 and the floor to allow forklifts to go in and out of the truck 9, which is backed to the dock 27 against the dock bumper 29.
The sensor 7 or sensor 6 will sense the wheel 8 to ensure a proper positioning of the chock 1, and the detector 18 of pivot 14 will signal the use of the extendable arm A. Proper positioning of the chock 1 is facilitated by articulations of pivot 14, upper joint 11 and lower joint 13. The truck presence detector 19 mounted on the bracket 20 will sense the truck 9 when approaching 4β5 inches from the dock bumper 29. In case the truck 9 will start to move away during the loading operation, dock leveller detector 21 interlocked with the dock leveller 26 together with the truck presence detector 19 will trigger alarm 22. All following detectors 6, 7, 18, 19 and 21 are operatively connected to the control panel 24 which will illuminate lights 23 and 25 to indicate when the loading operation is safe.
Such arrangement of using detectors to indicate the right setting of the chock is also a very important feature of the present invention because it eliminates all possible premature movements of the truck from the loading dock and prevents any accidents.
Chock 1 is made from high tensile weather resistant galvanized steel which is many times harder than conventional steel. All weather chock combined with non-skid plate can provide 60,000 lbs. of restraining force.
For both embodiments shown on
a, b and c show different modifications of the configuration of the base portion of the chock 1 and stoppers 4 of the supporting plate 3.
b shows angled teeth 2 of chock 1 cooperating with cylindrical stoppers 4b mounted transversally along the plate 3.
Teeth 2 of chock 1 have a hook-shaped configuration and are inclined under the angle in the range between 0 and 90 degrees. Preferably, the angle is chosen between 5 and 30 degrees.
a, b, and c show different modiflcations of the sensor 6 installed inside the body of the chock 1.
b shows a spring-activated sensor comprising a spring pivot 33, lever 34 and switch 33a. When wheel 8 engages the chock, it will rotate lever 34 activating the switch 33a. Spring 33 is adapted to bring lever 34 into the position, thus allowing the chock 1 to be set from any angle.
c shows an electronic sensor 36 installed by means of steel or rubber bracket 37 to shield it from strong vibration. Due to its save positioning inside the chock 1, sensor 36 is able to sense the wheel even when it is wet or during toughest weather conditions and to assure proper positioning of the chock 1. Such sensor can be wired, working on radio frequency or may be operated by any other means. The sensor 36 will detect the wheel 8 when properly set and send a signal to the control panel 24 that will activate light 23 or interlock with dock leveller 26. It also can be linked to the truck presence detector 19.
A differential pressure switch 50 is installed on the air input conduit 49 and is connected to the control panel 51 located in the building. Control panel 51 is connected to the alarm (anti-theft) system also located within the building. The chock 1 cannot be removed once switch 50 is activated by signal transmitted from the alarm system. If variation is sensed in pressure applied to the chock 1, the alarm system can be activated automatically.
A green light 52 inside the building is activated by means of the pressure switch 53 installed on the input air conduit 49 to control correct pressure inside the cylinder 40 and to properly position locking element 38. A red light 54 is activated by means of a detector 55 inside the chock 1. Detector 55 is activated by means of a stopper 56 attached to locking element 38. Detector 55 sends signal to a relay 57 that cuts power supplied to green light 52. In this case, stopper 56 will activate detector 55 only when locking element 38 does not make the necessary contact with the wheel 8 and extends to its limit. Red light 54 can warn of non-safe operation. An audible means can be added to signal danger, for example when chock 1 is positioned too far from the wheel 8 or beside it. A one-way valve 60 can be installed between air compressor 44 and pressure switch 47.
When loading operation takes place, fork lifts going inside the docked vehicle may cause some movement affecting change in pressure applied to locking element 38. To control this situation, an air reserve tank 58 equipped with a safety valve 59 will supervise such variation of the pressure and will prevent cylinder 40 from being overloaded.
It must be emphasized that when activated, the locking element 38 should abut the tire 8 to press it and lock the chock 1 in place. Such movement of locking element 38 will be within a certain range to facilitate proper positioning against the tire. In case locking element 38 will not be able to engage the tire, the locking device of chock 1 will signal this non-safe situation.
Embodiments shown on
The present invention has the following advantages over all known systems:
Thus, it can be seen that the objects of the present invention have been satisfied by the structure presented hereinabove. While in accordance with the Patent Statutes, only the best mode and preferred embodiments of the present invention have been presented and described in detail, it is to be understood that the invention is not limited thereto or thereby. Accordingly, for an appreciation of the true scope and breadth of the invention, references should be made to the following claims.
This application claims priority of provisional application no. 60/358,711, filed Feb. 25, 2002 and provisional application no. 60/367,784, filed Mar. 28, 2002, the contents of which are hereby incorporated by reference.
Number | Name | Date | Kind |
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4217831 | Koliba et al. | Aug 1980 | A |
4963068 | Gelder | Oct 1990 | A |
4969792 | Ellis | Nov 1990 | A |
4973213 | Erlandsson | Nov 1990 | A |
5025877 | Assh | Jun 1991 | A |
5312213 | Winsor | May 1994 | A |
5803208 | Blach | Sep 1998 | A |
6123496 | Alexander | Sep 2000 | A |
6336527 | Metz | Jan 2002 | B1 |
6505713 | Paul et al. | Jan 2003 | B1 |
Number | Date | Country |
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2164738 | Jun 1997 | CA |
Number | Date | Country | |
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20030159892 A1 | Aug 2003 | US |
Number | Date | Country | |
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60367784 | Mar 2002 | US | |
60358711 | Feb 2002 | US |