Transportable, one piece modular, automatic entry gate

Abstract

A one piece modular automatic lift gate comprising a lift stump, a lifting arm, at least one stanchion, a slab, a control box set inside a stanchion to house mechanical, electric and electronic components.

Description

BACKGROUND OF THE INVENTION

[0002] 1. Field of the Invention

[0003] The invention relates generally to entry gates or lift gates but more specifically to gates used in guarding private properties although it could be used to control access at temporary events such as festivals and other large public gatherings.

[0004] 2. Description of the Relevant Art

[0005] Lift gates and entry gates have been known in the art for centuries with the purpose of controlling access to specific areas. In recent years, innovations have mostly centered around electronic control systems. The prior art has very few examples of transportable, modular entry gate except perhaps for U.S. Pat. No. 4,630,395 by Nasatka. Even then, its structure is fundamentally different from the herein described invention. There is therefore no invention that provides for an entry gate which is easy and fast to install, economical to purchase and to maintain.

SUMMARY OF THE INVENTION

[0006] The purpose of this invention is to provide an entry gate that can be completely installed on site in a matter of hours instead of days. Installing a gate is a very complex undertaking which requires digging, assembling forms into which concrete is poured to serve as anchor for the pair of stanchions that usually flank both sides of an entry gate. Once the foundation is laid, wiring, motors, gears and all manners of mechanical, electric and electronic controls have to be assembled and debugged on site. This process is measured in days, when everything goes to plan.

[0007] This invention, because it arrives on site already assembled, only needs a narrow and shallow channel to be cut in the driveway, which can be done using a concrete saw and perhaps a jack hammer, once the channel is cut, it is levelled with a layer of sand or gravel poured into it. Once the channel has been prepared, the one piece modular entry gate is deposited in place. A long underground plastic pipe originating at the house and ending at the gate is used for running two sets of cables (AC wiring and electronic controls). This prep work only requires a few hours to execute and the positioning of the one piece gates from the truck, using a boom to drop it into the channel takes minutes. Connecting the wires, putting some caulking or sealant of some kind around the perimeter of the concrete slab also takes minutes. Finally, testing and programming the gate also takes minutes.

[0008] It is an object of this invention to provide a modular one piece modular automatic lift gate.

[0009] It is another object of this invention to provide a method for quickly installing the said modular one piece modular automatic lift gate.

[0010] It is a further object of this invention to provide for an economical, mass produced entry gate.

[0011] It is yet another object of this invention to provide for a lift gae which can be used for traffic control at temporary events.

[0012] It is a final object of this invention to provide for an entry gate with an easy installation method.

DESCRIPTION OF THE DRAWINGS

[0013] An embodiment of the present invention will now be disclosed, by way of example, in reference to the following drawings in which:

[0014] FIG. 1 Is a perspective view of the lift gate

[0015] FIG. 2 a Is a front elevation of the lift gate in the closed position

[0016] FIG. 2 b Is a front elevation of the lift gate in the opened position

[0017] FIG. 3 a Is a side elevation of the motor and control box

[0018] FIG. 3 b Is a front elevation of the motor and control box

[0019] FIG. 4 Is a front elevation of the automatic spring tensioner

[0020] FIG. 5 a Is a front elevation of the twin door gate showing the detail of the gearing system used for this embodiment.

[0021] FIG. 5 b Is a front elevation of the twin door gate

[0022] FIG. 6 Is a front elevation of the in-house control

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

[0023] FIG. 1 The lift gate 1, as seen from inside the property, is comprised of a lifting arm 2 which can also include a fence 3 as decorative element and said fence is comprised of posts 10 and a lower arm 11. An arm stopper 4 helps maintain the lifting arm 2 straight while also acting as a locking means by allowing for a lock to be installed if needed. At least one stanchion 5 is fixedly attached to a slab 6. For symmetrical reasons, a pair of stanchions 5 and 5′ as per FIG. 1 is preferable since it also allows for the arm stopper 4. The stanchion(s) is/are fixedly attached to the slab 6 along with the lifting arm 2, lower arm 11 and fence 3 to form a one piece module. Lampposts 7 can optionally be added to top off the stanchions 5 an 5′. A stub 12 which can originate from an extension of an address panel protrudes from the lamppost 7, its function will be described later. Anchor plugs 34 situated on the top face of the slab 6 cover the holes after the lifting hooks are removed. It's those lifting hooks that are used with hoisting cables when the lift gate 1 is put into place and are no longer needed in case of a permanent installation but can be reinstalled quickly in case of a temporary installation. It is obvious that in temporary situations when digging a trench is not practical, ramps placed on each side of the slab 6 provide for easy passage of vehicles.

[0024] FIG. 2 a Inside stanchion 5 can be found a control box 8 which prodvides all the mechanical, electrical and electronic systems that actuate the lift gate 1. Sticking out of the control box 8 and the stanchion 5 is a lift stump 9 (in dotted lines)which fits inside the lifting arm 2. This lift stump 9 is what lifts the entire lifting arm 2, fence 3 and lower arm 11. Inside the slab 6 is a conduit 35 through which runs the wiring for the lamppost 7 on stanchion 5′ and the photocell and any other system that needs wiring such as control keypad, intercom and camera. Joined to the conduit 35 is the external wiring conduit 38 which picks up the incoming wires providing power and electronic control.

[0025] FIG. 2 b When the lifting arm 2 is raised, the fence 3 folds as indicated to allow for a wider opening. Each posts 10 of the fence is rotatably attached to both the lifting arm 2 and the lower arm 11. The stub 12 acts as a means to secure proper stoppage of the lift gate 1 when it is fully up. This prevents possible “kicks” or overruns as the motor 13 (not shown) ends its course. It should be noted that the lower arm 11 is not attached in any way directly to the stanchion 5 but is rather rotationally attached to the posts 10.

[0026] FIG. 3 a This side elevation shows the inside of the control box 8 that fits inside a stanchion 5 (in dotted lines) where can be found all the mechanical, electrical and electronic components. For the sake of simplicity, only the main components are identified: A motor 13, electronic control board 36, drive chains 14 and 14′, a pair of small gears 15 and 15′, a first large gear 16 and a second large gear 17. The second large gear 17 has an axle 18 running through it and around said axle 18 are wrapped a pair of coil springs 19, one on each side of the said second large gear 17. The axle 18 has one end terminating outside the control box 8 and this end is preferably serrated to insure adequate frictional attachment with the lift stump 9.

[0027] A pair of on gear stopper 20 and a pair of on box stopper 21 so named since the pair of on gear stopper 20 is affixed to the second large gear 17 while the pair of on box stopper 21 is affixed to the walls of the control box 8. The coil springs 19 act much like a counterweight in the sense that they reduce the load that the motor 13 would have to bear in lifting the gate 1 and they also act as safety measure since they won't allow the gate 1 to fall even if the a chains 14 or 14′ or the motor 13 were to break. The springs 19 are strong enough to lift the gate 1 all by themselves.

[0028] FIG. 3 b In this front elevation of the inside of the control box 8 we can see the motor 13, a better view of the chains 14 and 14′, the small gears 15 and 15′, the first large gear 16 and the second large gear 17, the coil springs 19 with their on gear stoppers 20 and on box stoppers 21. Over time, the coil springs 19 can lose their tension and for that, a semi-automatic spring tensioner 22 (FIG. 4) has been devised: Normally, the second large gear 17 does one quarter of a revolution in order to open or close the gate which makes the coil spring 19 move from position “A” when opened to position “B” when closed. Over time, because the spring is most often in position “B” (gate closed) it will become weaker when it gets to position “A”.

[0029] FIG. 4 To correct that, the electrical shutoff system 22 is cheated by moving a first electrical contact 23a closer to a roving contact 37 by turning its associated leading screw 24 which brings the stop position of the coil spring 19 to position “C” (FIG. 3b) Since this has the effect of altering the final opened position of the axle 18 which results in the fence 3(not shown) not being fully opened, this can be easily fixed by removing the stump 9 (FIG. 2a) (the lift arm having already been removed for the purpose of maintenance) from the axle 18 and repositioning it. But when the roving contact 37, (which has a leading screw actuated by the revolving motor) moves towards the second electrical contact 23b, the gate will stop a little short of its intended closed position but this is corrected by moving the second electrical contact 23b farther off by also turning its associated leading scew 24′. In this way, the tension in the coil springs 19 can be maintained for many years. The spring tensioner 22 itself is taken from a system typically found in electric garage door openers. In fact most of the electrical system is derived from existing electric garage door opening systems. In this case a new and unobvious function has been found for electric garage door opening systems.

[0030] FIG. 5 a This front elevation shows an alternate embodiment of the gate as a twin door entry gate 25. The gearing system has essentially the same gear sequence as the other embodiment except that the configuration is different. The motor 13 is situated at the top of the stanchion 5 to be easily accessible through a removable panel 26 for servicing. It is then followed by the same gear sequence 15′, the chain 14 and the first large gear 16. After that, the sequence changes with the addition of a first transitional gear 39 a transitional chain 40 and a second transitional gear 39′ is fixedly attached to a long shaft 41 which leads to the fixedly attached second small gear 14 and again, following the same sequence as in FIG. 3a where the chain 15 leads to the second large gear 17 which has an axle 18 running through it but that axle has a distal end fixedly attached to a driving gear 41 which drives a long closed loop chain 27 which in turn, joins two posts 28 and 28′ (dotted lines) that are each fixedly attached to one door gate 25.

[0031] FIG. 5 b This top view shows how the long closed loop chain 27 joins the two posts 28 and 28′ by way of the driving gear 41 which actuates the long closed loop chain 27 which drives both post gears 42 and 42′. Both post gears are integral parts or at least fixedly attached to the posts 28 and 28′ respectively. By being twisted, the long closed loop chain 27 makes the gear associated with post 28′ turn in the opposite direction than post 28 so that the twin door entry gate 25 can open properly. By removing the long closed loop chain 27 and leaving just a smaller chain between the driving gear 41 and the first post gear 28, a single door entry gate could be made.

[0032] FIG. 6 Is a front elevation of the in-house control 29 featuring a light button 30 to turn the lights on or off with a light indicator LED 31 that confirms the status (LED on for lights on) and a gate button 32 to open and close the gate with an accompanying gate LED 33 that is turned on when the gate is opened. Besides the in-house control, it should be understood that there is also a remote control for the car as well as a keypad access directly on one of the stanchions 5. The entry gate herein described also makes provisions for various options such as cameras connected to a website, alarm system linked with the house alarm system and all such technologies to come. Also, from the above description, it is inferred that the first embodiment of the lift gate 1 could be comprised of two lifting arms 2 in order to have a double lifting gate by simply adding a second control box 8 inside a second stanchion 5.

Claims

1. A one piece modular automatic lift gate comprising: a lift stump, a lifting arm, at least one stanchion fixedly attached to a slab; a control box set inside a stanchion to house mechanical, electric and electronic components.

2. A modular one piece automatic lift gate as in claim 1 further comprising: an arm stopper situated on a second stanchion set at the opposite end of the slab from the first stanchion for stopping, holding and/or locking the arm at its lowered position; a stub to act as a stopper to the arm when said arm is in its raised position.

3. A one piece modular automatic lift gate as in claim 1 further comprising: Anchor plugs on the top face of the slab covering holes wherein hooks can be inserted into.

4. A one piece modular automatic lift gate as in claim 1 further comprising: a slab with a conduit running therethrough and within which said conduit runs electrical and electronic control wires; a conduit further comprised of an external wiring conduit extending therefrom.

5. A one piece modular automatic lift gate as in claim 1 further comprising: A lifting arm having fence posts rotatably attached and hanging therefrom; a stub to act as a stopper when the lift arm is in raised configuration and; an arm stopper to act as a stopper and/or locking means when the lift arm is in lowered configuration.

6. A one piece modular automatic lift gate as in claim 1 further comprising: the control box having a motor, at least one electronic control board, drive chains, a pair of small gears, a first large gear and a second large gear;. the second large gear having an axle running through it and around said axle are wrapped a pair of coil springs, one on each side of the said second large gear; a pair of on gear stopper and a pair of on box stopper affixed to the second large gear and the pair of on box stopper affixed to the walls of the control box.

7. A method of adjusting spring tensions in a self contained automatic lift gate comprising the steps of: moving the electrical contact closer to the roving contact by turning its leading screw which brings the stop position of the coil spring to an alternate position; removing the lift stump from the axle and repositioning it; moving the other electrical contact farther off by turning its leading scew.

8. A one piece modular automatic lift gate comprising: at least one stanchion, a slab; a motor, at least one electronic control board; drive chains, a pair of small gears, a first large gear and a second large gear, a first transitional gear, a transitional chain and a second transitional gear fixedly attached to a long shaft leading to a fixedly attached second small gear a chain leading to the second large gear having an axle running through and said axle having a distal end fixedly attached to a driving gear which drives a closed loop chain actuating at least one post and said post being fixedly attached to a door gate.

9. A one piece modular automatic lift gate as in claim 8 further comprising: a long looped chain joining two posts by being twisted so that the second post turns in the opposite direction than the first post so that two doors can open.

10. A method of installing a self contained automatic lift gate comprising the steps of: carving a channel configured and sized so as to receive the slab; adding levelling material into the channel; depositing the modular one piece entry gate in place; connecting incoming wires to the lift gate wiring; putting caulking or sealant around the perimeter of the slab; testing and programming the gate.