ES2624491T3 - Tourniquet - Google Patents

Abstract

Full height tourniquet (10) comprising a cage structure (20) and a rotor (30) attached with rotational capacity thereto, said rotor (30) comprising a substantially vertical axis (31) and a plurality of arms ( 32, 33, 34) which extend perpendicularly thereto in different radial directions, in which said arms (32, 33, 34) are mutually separated along said axis (31) and are grouped in a plurality of radial planes angularly separated from each other, characterized in that the shaft (31) of the rotor (30) comprises a plurality of consecutive modular sectors (36, 37, 38) that can be mounted to each other, whereby different amounts of modular sectors allow manufacturing turnstiles of different heights, and why the arms (32, 33, 34) are arranged between consecutive sectors that perform the functions of separators between the arms (32, 33, 34).

Description

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DESCRIPTION

Tourniquet

The present invention refers, in general, to access control systems and, in particular, to a full height turnstile used to regulate or limit the access of people to stadiums, public spaces, subway stations and the like.

The known access regulation systems comprise a cage structure and a rotor with a vertical axis comprising a plurality of arms that extend horizontally therefrom in radial directions. This type of access regulation system is commonly known in the sector as "full height turnstile" and is used, in general, whenever a high level of security is needed in places without personnel.

The rotor arms are separated along the axis of the rotor and are grouped in a plurality of radial planes angularly separated, for example, three planes arranged with a separation of 120o between them or four planes arranged at 90o each other, defining from this mode a plurality of doors.

The cage structure generally includes a first vertical wall that has, for example, an arc shape, arranged close to the free ends of the rotor arms. In this way, a suitable opening is defined to allow the passage of one or several people at the same time between the vertical wall and the rotor shaft. The opening is periodically closed by means of the doors formed by the rotor arms aligned in the different radial planes.

In addition, the cage structure generally comprises a second vertical wall formed by a plurality of bars that have a size and shape that are similar to those of the rotor arms. The bars are subject, for example, to a vertical support from which they extend horizontally towards the rotor shaft. In order not to interfere with the rotor during its rotation, the bars are separated along the vertical support and are equidistant respectively from the consecutive rotor arms, so that during the rotation of these they are periodically intertwined with their arms. This configuration allows to obtain a tourniquet that includes a single step, in which the direction of rotation of the rotor determines the direction of unique direction for the people who must cross the step.

Known full-height turnstiles include rotors in which the arms are mounted on the shaft, for example, in correspondence with the appropriate openings or housings by means of screws or bolts. Examples of these types of turnstiles are described in US Patents 2170192, USA 3318045 and USA 3839825.

The possibility of releasing the arms from the shaft has the advantage of reducing the total size of the rotor during transport and allowing the arms to be disassembled in an emergency, for example, when a person is stuck in the passage of the turnstile.

Despite the numerous types of full height turnstiles known in the sector there is still a need to improve their structural and functional characteristics, which is an objective of the present invention. Said objective is achieved with a full height turnstile whose main characteristics are specified in the first claim, while other characteristics are specified in the other claims.

An idea of the underlying solution of the invention is to disclose a full height turnstile in which the rotor shaft is not formed as a single piece, but comprises a plurality of modular sectors that can be mounted with one another.

The main advantage provided by the invention is, therefore, the complete modular structure of the rotor, that is, the possibility of assembling and disassembling not only the arms but also the shaft, which makes it easier to transport the rotor, as well as make that the turnstiles have several heights very easily and at a low cost by using a different number of modular sectors and arms.

According to the invention, the rotor arms are arranged between subsequent or consecutive modular sectors that perform the function of separators between the arms, thereby greatly simplifying the assembly and disassembly operations of the rotor and dramatically reducing the time it takes. The modular sectors can advantageously comprise suitable housings to facilitate the mutual orientation of the rotor arms and their alignment in the respective radial planes.

To further facilitate assembly operations, the groups of rotor arms provided to be arranged at the same height in the different radial directions can be pre-assembled together, advantageously, that is, be mounted to each other before being mounted. in the rotor

According to a preferred embodiment of the invention, the groups of arms provided to be arranged at each height are mounted to each other using a joint in which a plurality of radial openings are formed. The

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union is configured to be embedded and hidden between consecutive hollow sectors, so that the mounted rotor is substantially identical to a traditional type rotor.

The advantages and additional features of the full height tourniquet according to the present invention will be apparent to those skilled in the art from the following detailed and non-limiting description of the embodiments thereof with reference to the attached drawings in which:

- Figure 1 is a perspective view showing a full height tourniquet according to an embodiment of the invention;

- Figure 2 shows the full height turnstile rotor shown in Figure 1;

- Figures 3 to 9 are perspective views, showing the subsequent stages of mounting the turnstile rotor of Figure 1;

- Figure 10 is a perspective view showing a joint to previously mount the turnstile rotor arms of Figure 1.

Referring to Figures 1 and 2, the full-height turnstile -10- according to the invention comprises a cage structure -20- and a rotor -30- attached with a turning capacity thereto. The rotor -30- comprises an axis -31- which, under operating conditions, is arranged perpendicularly to the ground, therefore vertically, and a plurality of arms that extend perpendicularly thereto in different radial directions, therefore horizontally with reference to the same operating conditions.

The rotor arms -30- are separated along the axis -31- and are grouped in a plurality of radial planes angularly separated from each other. In the embodiment shown, the tourniquet -10- comprises, for example, three groups of arms indicated respectively by the reference numbers -32-, -33- and -34-, which are aligned in three respective radial planes mutually separated from each other. An angle of 120o.

The cage structure -20- comprises, in general, a first vertical wall -21- having an arc shape, for example, arranged close to the free ends of the rotor arms -30-. The vertical wall -21- defines together with the rotor shaft -31- a suitable opening to allow the passage of one or several people at the same time. This opening is periodically closed by the groups of the rotor arms aligned in the respective radial planes.

The cage structure -20- also comprises a second wall -22- generally vertical provided with a plurality of straight elements -23-, for example bars having a shape and size similar to those of the arms -32-, -33- , -34- of the rotor -30-. The straight elements -23- are subject to a vertical support -24- from which they extend horizontally towards the rotor -30-. In order not to interfere with the turnstile during its rotation, the straight elements -23- are separated along the vertical support -24- and are equidistant respectively from the consecutive arms of the rotor -30-, so that during the rotation of the latter periodically intertwine with the arms -32-, -33-, -34- of the rotor -30-.

To allow mounting of the rotor -30-, the cage structure -20- comprises a base -25- adapted to allow positioning and centering the axis -31- of the rotor -30- on a lower end thereof and a roof - 26- which comprises a housing (not shown) configured to receive and hold with rotation capacity the opposite end of the shaft -31- of the rotor -30-, that is, the upper end. In the embodiment shown, the rotor -30- comprises a drive pin -35- disposed at its upper end, which can be coupled by means of actuation, usually an electromechanical device, or alternatively an electric motor, housed in a receptacle -27 - arranged on the roof -26- of the cage structure -20-. In the embodiment shown, the drive pin -35- has a square cross section, for example.

According to the present invention, the shaft -31- of the rotor -30- of the turnstile -10- comprises a plurality of modular sectors that can be mounted with one another. Under operating conditions, the modular sectors are axially attached to each other, thereby forming a single element such as a rod, the height of which depends substantially on the number or number of modular sectors mounted to each other.

In the embodiment shown, the modular sectors have a cylindrical shape, whose cross section is substantially circular.

The sectors are preferably hollow to achieve a total lightweight structure of the rotor -30- mounted.

It will be understood that the cylindrical shape of the sectors does not limit the invention and that the sectors could have prismatic shapes, for example. It will also be understood that the invention is not limited to sectors that have a concave structure.

The arms -32-, -33-, -34- of the rotor -30- are arranged and held along the axis -31- between sectors

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consecutive, so that the sectors perform a function of holding the arms, as well as a function of separation between them allowing to arrange the arms at different predefined levels or at different predefined heights in relation to the ground. In the embodiment shown, the sectors advantageously comprise housings that have a shape corresponding to the shape of the arms -32-, -33-, -34-, whose housings facilitate the positioning of the arms, their mutual orientation in the axis -31- of the rotor -30- and its alignment in the respective radial planes.

This configuration also makes it possible to simplify rotor assembly operations -30-, because the sectors and arms are mounted sequentially to each other, taking advantage of their respective complementary geometric shapes for mutual alignment.

The housings for the arms -32-, -33-, -34- of the rotor -30- are preferably formed at the free ends of each sector, so that the arms -32-, -33-, -34- are enclosed between consecutive sectors. In the embodiment shown, the arms have circular cross sections, for example, and the housings formed at the ends of the sectors have, consequently, a semicircular shape.

The assembly of the shaft -31- of the rotor -30- is preferably carried out using braces inserted coaxially across the sectors. Depending on the height of the shaft -31- of the rotor -30-, that is, the number of modular sectors, a single tie or a plurality of connected struts can be used.

Referring now to Figures 3 to 9, the subsequent assembly stage of the rotor -30- will be described.

As shown in Figure 2, to mount a rotor -30-, a first sector -36- is used to form the lower end of the shaft -31-. A first group of arms is placed on this first sector -36-, specifically three arms -32-, -33-, -34- which are housed in the respective semicircular housings formed at the end of the sector -36-.

The first sector -36- is closed at one end by means of a base comprising an axial hole adapted to receive a munon -40- to fix a tie -41 -, for example, a threaded munon. The munon -40- inserted in the hole formed in the first sector -36- protrudes beyond the arms -32-, -33-, -34- in the axial direction, allowing the mounting of the tie -41-. The tie -41- can be fixed to the pin -40- directly or, as in the embodiment shown, by means of a threaded tubular element -42- or equivalent coupling means well known to those skilled in the art.

Once the strap -41- has been mounted, a second sector -37- is mounted and placed on the first group of arms -32-, -33-, -34-. Next, a second group of arms -32-, -33-, -34- is mounted on the second sector -37- and the assembly proceeds in this way alternating additional sectors -37- and additional groups of arms -32-, - 33-, -34- until the desired rotor height -30- is achieved.

Once the assembly of the modular sectors -37- and that of the arm groups -32-, -33-, -34- is completed, as explained above, a sector -38- is mounted on the upper end of the axis -31- of the rotor -30-, for example, a sector that has a shape similar to that of the sector -36- that forms the lower end of the rotor -30-. The drive pin -35- can be mounted in the sector -38-.

In the embodiment shown, the sectors -36- and -38- that respectively form the lower and upper ends of the shaft -31- of the rotor -30- have a lower height than the sectors -37- used to form the shaft part - 31- of the rotor -30- arranged between its ends. However, it will be understood that this aspect does not limit the invention and that additional sectors that have a shape similar to that of the sectors -37- could also be used to form the ends of the rotor.

According to a further aspect of the invention, to further facilitate assembly operations, the groups of arms -32-, -33-, -34- intended to be arranged at the same height along the axis -31- of the rotor -30- in different radial directions they can be advantageously mounted to each other.

Referring next to Figure 10, according to a preferred embodiment of the invention, the groups of arms -32-, -33-, -34- of each level or height are mounted to each other by means of a union -50- comprising a substantially cylindrical body in which a plurality of radial openings formed to receive the arms -32-, -33-, -34- are formed.

The body of the union -50- is configured to fit in the cavities formed in the hollow sectors -36-, -37-, -38-, so that the overall appearance of the mounted rotor -30- is substantially identical to the aspect of A traditional type rotor. The union -50- is equipped with a central hole -51- configured to allow the passage of the strut or braces -41 - used to mount the rotor -30-.

The union -50- is preferably manufactured in two halves that can be assembled to each other, which simplifies its manufacture due to the substantial absence of weakening problems and the union can be

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Made of plastic materials through an injection molding process. As shown in Figure 10, the assembly of the two halves of the union -50- and of the arms -32-, -33-, -34- located therein can be carried out by means of screws, for example.

The arms -32-, -33-, -34- are not connected to the rotor -30- directly, but through the respective brackets -60- of the turnstile -10- configured to fit in the union -50- described above. This solution is advantageous because it allows mounting on the same support and, therefore, on the union and the rotor, arms that have different shapes and / or are made of different materials, thus increasing the degree of modularity of everything the full height turnstile. In addition, this solution allows you to quickly replace an arm in case of deformation or breakage without being obliged to disassemble the entire rotor.

As shown in Figure 10, each support -60- comprises a plate -61- adapted to fit into a housing formed in the joint -50- and having the corresponding shape. The support -60- also comprises a counterplate -62- adapted to rest against the outer surface of the rotor -30- and having a corresponding shape thereto. A fixing element -63- configured to receive an arm is fixed to the counterplate -62-. The fixing element can comprise, for example, a pair of flanges between which a rotor arm can be inserted and fixed.

Although in figure 10 the counterplate -62- and the fixing element -63- are shown as independent components, it will be understood that they could also be manufactured in one piece.

In an assembled configuration, the plate -61-, the counterplate -62- and the fixing element -63- are preferably fixed by means of a screw -64- inserted in the fixing element -63- and coupled to a threaded hole formed on the plate -61 -.

As shown in the figure, in an assembled configuration, the plate -61- and the counterplate -62- are radially separated. In order to avoid deformation of these components when the screw -64- is tightened, a separator -65- can be adapted advantageously between the plate -61- and the counterplate -62-. In the embodiment shown, the separator is integrally formed with the counterplate -62-, for example.

The embodiments of the invention described and shown herein are only susceptible examples of numerous variants. For example, as an alternative to the use of a joint -50-, the arms -32-, -33-, -34- of each group could be fixed together by welding, thus simplifying all assembly operations and making the rotor structure -30- be economical. Also, as an alternative to the braces -41-, the sectors -36-, -37-, -38- could be mounted to each other using threaded bolts and corresponding threaded holes fixed thereto at their ends.

Claims (11)

5 10 fifteen twenty 25 30 35 40 Four. Five 1. Full height tourniquet (10) comprising a cage structure (20) and a rotor (30) attached with rotation capacity, said rotor (30) comprising a substantially vertical axis (31) and a plurality of arms (32, 33, 34) that extend perpendicularly thereto in different radial directions, in which said arms (32, 33, 34) are mutually separated along said axis (31) and are grouped in a plurality of radial planes angularly separated from each other, characterized in that the shaft (31) of the rotor (30) comprises a plurality of consecutive modular sectors (36, 37, 38) that can be mounted to each other, whereby different amounts of modular sectors allow manufacture turnstiles of different heights, and why the arms (32, 33, 34) are arranged between consecutive sectors that perform the functions of separators between the arms (32, 33, 34). 2. Turnstile (10), according to claim 1, wherein the sectors (36, 37, 38) comprise housings having a shape corresponding to the shape of the arms (32, 33, 34), said housings being formed in the free ends of the sectors (36, 37, 38). 3. Turnstile (10) according to claims 1 or 2, wherein the sectors (36, 37, 38) are mounted by means of braces (41) inserted coaxially therethrough. 4. Turnstile (10) according to any one of claims 1 to 3, wherein the sectors (36, 37, 38) are hollow. 5. Turnstile (10) according to any of claims 1 to 4, wherein the groups of arms (32, 33, 34) provided to be arranged at the same height along the axis (31) of the rotor (30) ) in different radial directions are mounted to each other. 6. Turnstile (10) according to claim 5, wherein the groups of arms (32, 33, 34) at each height of the shaft (31) of the rotor (30) are mounted to each other through a joint ( fifty). 7. Turnstile, according to claim 6, wherein said joint (50) comprises a substantially cylindrical body in which a plurality of radial openings formed to receive the arms (32, 33, 34) are formed. 8. Turnstile (10), according to claim 6 or 7, wherein the sectors (36, 37, 38) are hollow and said cylindrical body of the joint (50) is sized such that it can fit into the hollow sectors (36, 37, 38). 9. Turnstile (10) according to any of claims 6 to 8, wherein the body of the joint (50) is composed of two halves that can be mounted on each other. 10. Turnstile (10), according to any of claims 6 to 9, further comprising a plurality of brackets (60) configured to fit the joint (50) and to allow mounting of the arms (32, 33, 34) on the rotor (30). 11. Turnstile (10), according to claim 10, wherein each support (60) comprises a plate (61) adapted to fit into a housing of a corresponding shape formed in the joint (50), a counterplate (62) adapted to rest against the outer surface of the rotor (30) and having a shape corresponding to the shape of the rotor (30) and a fixing element (63) configured to receive an arm (32, 33, 34).