This application is a 371 of PCT/EP2017/065718 filed on Jun. 26, 2017, published on Jan. 4, 2018 under publication number WO 2018/001966, which claims priority benefits from Swedish Patent Application No. 1630166-5 filed Jun. 29, 2016, the disclosure of which is incorporated herein by reference.
The present invention relates to a floor pit covering system to be used primarily in relation to large vertical lifting doors, and a method of operating such a system.
Vertical lifting doors are frequently used for extremely large door openings, such as those of aircraft hangars and shipyard halls. In certain applications, it may be advantageous to split a large opening into two or more smaller openings using a pivotable mullion system. Such a solution increases the flexibility of the door system, while also saving energy.
The lower end of a conventional mullion is provided with a pin which is to be inserted into a corresponding floor pit. In order to avoid accidents, e.g. caused by stepping into a floor pit, and to allow vehicles to pass over a floor surfaces, each floor pit is provided with a pivotable cover plate, covering the floor pit opening. These cover plates have to be opened and closed manually, which is a heavy and time consuming process. Further, opening/closing of one or more floor pits could easily be forgotten, resulting in damage to personnel, doors or vehicles.
It is an object of the present invention to mitigate the above problems, and to provide a floor pit covering system which can be constructed by standard components. According to a first aspect of the present invention, these objects are achieved by a floor pit covering system comprising a cover plate and a pivoting system, the pivoting system being adapted for arranging the cover plate in a first end position or in a second end position in response to an internal force, or an internal force and an external force, being applied onto the cover plate, the cover plate being arranged in the first end position when force FE≤FI and in the second end position when force FE>FI.
Such a solution allows the floor pit covering system to be operated automatically without personnel having to open each floor pit manually. Further, the risk of damaging the mullion, the motorized base pin, the mullion lifting cable or the floor pit covers is significantly reduced. Further, the tripping hazard is greatly reduced as well as the risk of personal injury from stepping into an opening in the floor.
In one embodiment, the pivoting system comprises an articulated joint system and at least one spring, constituting a simple and well-tried solution for transferring forces between vertical and horizontal directions.
The internal force may be generated by the spring.
The cover plate may be arranged at a first end of the articulated joint system, and the spring may be arranged at a second end of the articulated joint system, such that the length of the articulated joint system is kept to a minimum.
In one embodiment, the articulated joint system comprises a plurality of interconnected components.
In a further embodiment, the spring is compressed when the cover plate is arranged in the second end position, allowing the internal force, generated by the spring, to move and hold the cover plate in the first end position as long as no external force is generated by a mullion pin.
The first end position may be a horizontal position and the second end position may be a vertical position.
In one embodiment, the floor pit is closed when the cover plate is arranged in said first end position, and the floor pit is open when the cover plate is arranged in the second end position, restricting the floor pit to the options of either being closed or receiving a mullion pin.
According to a second aspect of the present invention, these objects are achieved by a method of operating a floor pit covering system according to the above, comprising the steps of: applying an internal force onto the cover plate such that the cover plate is held in a first end position, applying an external force onto the cover plate, moving the cover plate to a second end position when force FE>FI, holding the cover plate in the second end position as long as force FE>FI, removing the external force from the cover plate, returning the cover plate to the first end position when force FE≤FI. This method allows the floor pit covering system to be operated automatically without personnel having to open each floor pit manually. Further, the risk of damaging the mullion, the motorized base pin, the mullion lifting cable or the floor pit covers is significantly reduced. Further, the tripping hazard is greatly reduced as well as the risk of personal injury from stepping into an opening in the floor.
In one embodiment, the first end position is a horizontal position, and the second end position is a vertical position.
In a further embodiment, the floor pit is closed when the cover plate is arranged in the first end position, and the floor pit is open when the cover plate is arranged in the second end position, restricting the floor pit to the options of either being closed or receiving a mullion pit.
Generally, all terms used in the claims are to be interpreted according to their ordinary meaning in the technical field, unless explicitly defined otherwise herein. All references to “a/an/the [element, device, component, means, etc.]” are to be interpreted openly as referring to at least one instance of said element, device, component, means, etc., unless explicitly stated otherwise. Further, by the term “comprising” it is meant “comprising but not limited to” throughout the application.
This and other aspects of the present invention will now be described in more detail, with reference to the appended drawings showing a currently preferred embodiment of the invention.
As previously mentioned, vertical lifting doors are used when covering extremely large door openings. A very large door opening may be split into several smaller door openings using smaller door sections 5 and pivotable mullions 6 arranged between each such door section, as shown in
Each mullion 6 is hinged, at its upper end, to the upper edge of the door opening. Further, each mullion 6 is connected to lifting means, such as cables 7. Consequently, the mullion 6 is upwardly foldable and of a so called “swing-up mullion” type. The opposite, lower end of the swing-up mullion 6 only rests against a floor, such as a concrete floor, when the mullion extends completely vertically, i.e. when the door opening is to be, at least partially, sealed off using the above mentioned door sections 5.
In order to fixate the mullion 6 in its vertical position, its lower end has to interconnect with the floor. Conventionally, the lower end is provided with axially movable locking means such as a pin 8. The pin 8 is operated by means of a motor, and is slid, from the interior of the mullion 6, vertically downwards such that it protrudes from the end of the mullion into a corresponding opening in the floor, a floor pit 9. Correspondingly, when the mullion 6 is to be folded upwards, the pin is moved axially back into the interior of the mullion 6.
The present invention relates to a floor pit covering system used for automatically opening and closing a floor pit in response to the presence, or absence, of a mullion. The floor pit covering system comprises a pit cover plate 1 and a pivoting system 2, as shown in
The pivoting system 2, which comprises an articulated link system 3 and at least one spring 4, is adapted for arranging the cover plate 1 in a first end position P1 as shown in
The first end position P1 for the cover plate 1 is a horizontal position and the second end position P2 is a vertical position. I.e., the floor pit 9 is closed by the pit cover plate 1 that extends flush with the floor in the opening 11 of the pit base plate 10 when arranged in the first end position P1, and the floor pit is open when the cover plate 1, is extending downward into the floor pit 9 and essentially perpendicular to the plane of the floor, is arranged in the second end position P2.
As shown in
With particular reference to
As mentioned here above the cover plate 1 is attached to the free first end of the swing arm 3b. A second end of the swing arm 3b is pivotally attached to the first bracket 3e. Further, a first end of the rod 3a is pivotally attached to a first end of the crank 3c. A second end of the crank 3c is pivotally attached to a first end of the connection link 3d. The crank 3c functions as a lever between the spring 4 and the swing arm 3b for the pit cover 1 having an intermediate section pivotally attached to the first bracket 3e. A second end of the connection link 3d is pivotally attached to the first end of the swing arm 3b under the cover plate 1.
As mentioned, this pivoting system 2 is used for holding and moving the cover plate 1 between the two end positions P1, P2. During cover plate movement, the members in the link system 3 move, while the first and second brackets 3e, 3f are fixed. The axially movable rod 3a is allowed to pivot slightly at its second end during the movement of the cover plate 1. The crank 3c pivots around its intermediate section. The connection link 3d extending between the crank 3c and the swing arm 3b, pivots about both ends. The axially movable rod 3a pivot slightly about the pin 13 and moves in a horizontal direction, in a direction towards the cover plate 1 when the cover plate 1 is moved from the first end position P1 to the second end position P2. Correspondingly the axially movable rod 3a moves in a direction from the cover plate 1 when the cover plate 1 is moved from the second end position P2 to the first end position P1.
As a result of the above, the internal force FI is generated by spring 4. The spring 4 is compressed when the cover plate 1 is moved from the first end position P1 to the second end position P2 by the external force FE, and held in the second end position P2 by the very same force FE. The spring 4 is released when the cover plate 1 is moved from the second end position P2 to the first end position P1, and held in the first end position P1. The force generated by the released spring, the internal force FI, is sufficient to hold the cover plate 1 in the first end position P1. In order to hold the cover plate 1 in the second end position P2, the external force FE, generated by the pressure applied by pin 8, has to be larger than the internal force FI generated by the compressed spring 4.
As previously mentioned, the floor pit covering system is used for covering a floor pit 9. The components of the floor pit covering system are adapted to the dimensions of the actual floor pit 9. E.g., the cover plate 1 may have dimensions corresponding to the size of the mullion pin 8.
As mentioned here above the present floor pit covering system may also be provided with a service plate or a hatch 12, which can be removed such that access to the interior of the floor pit 9 and the spring 4 is allowed. This way, the spring force may be set, when mounted, by accessing the floor pit. Further, the floor pit covering system is hereby easily accessed for service.
The spring 4 surrounding the axially movable rod 3a is preferably a disc spring, and the spring force is set be means of a number of exchangeable washers or shims. The spring force is easily adjusted by changing the number of washers, shims or use of similar means. The washers are fitted to the end of the rod 3d by means of the abutment 14 at the second end of the axially movable rod 3a. The abutment 14 is comprised of a hex nut located at the end of the axially movable rod 4a.
With reference to
An internal force FI is applied onto the cover plate 1 such that the cover plate 1 is held in a first, horizontal end position P1, closing the floor pit. The internal force FI is permanently generated by spring 4, the spring 4 being released in the extended position when the cover plate is held in the first end position P1. The internal force FI, generated by the extended spring, is large enough to not only overcome the downwards directed force generated by the weight of the cover plate 1 and pivoting linkage system 3, but also any downwards directed force generated by a vehicle or an individual applying weight onto the cover plate 1.
When splitting the door opening into several smaller door openings by means of mullions 6, an external force FE is applied onto the upper side of the cover plate 1 by the pin 8. This external force FE is set large enough to overcome the predetermined limit value set for the internal force FI of the pivoting system 2. When the external force FE is larger than the opposing internal force FI, the cover plate 1 is moved from the first horizontal end position P1 to the second vertical end position P2, opening the floor pit, holding the cover plate 1 in that position for as long as the external force FE is larger than internal force FI, hence allowing the pin 8 to enter the floor pit 9. This movement is facilitated by the pivoting linkage system 3, which generate movement of rod 3d in a direction towards the cover plate 1, compressing the spring 4, and retracting the pivoting system 2 to its smallest horizontal length, i.e. the smallest possible distance between end positions E1 and E2.
When the mullion 6, and the pin 8, is removed, the external force FE is removed from the cover plate 1. As a result thereof, the external force FE becomes smaller or equal to the internal force FI, allowing the previously compressed spring 4 to release and extend. Releasing the spring 4 generates movement of rod 3d in the direction from the cover plate, which in turn pivots the linkage system 3, allowing the pivoting system 2 to extend to its largest horizontal length, i.e. the largest possible distance between end positions E1 and E2, and returning the cover plate 1 to the first end position P1.
Number | Date | Country | Kind |
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1630166-5 | Jun 2016 | SE | national |
Filing Document | Filing Date | Country | Kind |
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PCT/EP2017/065718 | 6/26/2017 | WO |
Publishing Document | Publishing Date | Country | Kind |
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WO2018/001966 | 1/4/2018 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
2264182 | Miller | Nov 1941 | A |
3217784 | Wolf et al. | Nov 1965 | A |
3672098 | Webb, Jr | Jun 1972 | A |
4050723 | Papadatos | Sep 1977 | A |
6385916 | Marko | May 2002 | B1 |
Number | Date | Country |
---|---|---|
202014000197 | Nov 2014 | DE |
1258586 | Nov 2002 | EP |
1275806 | Jan 2003 | EP |
1405977 | Apr 2004 | EP |
1536094 | Jun 2005 | EP |
668560 | Mar 1952 | GB |
Entry |
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International Search Report and Written Opinion mailed in PCT/EP2017/065718 dated Aug. 29, 2017. |
Swedish Search Report mailed in SE 16301765-5 dated Dec. 30, 2016. |
Number | Date | Country | |
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20190194994 A1 | Jun 2019 | US |