ES2616627T3 - Guide piece with an internal pulley - Google Patents

Abstract

Guide piece for the support of the ropes of a pleated mosquito net, with a hollow chamber and openings facing its four sides, an upper opening (17), a lower opening (18), a front opening with hole (20) and a rear opening (19), a pulley (23) consisting of a cylinder (33) with cylindrical side walls (32), which rotates around an axis (22) mounted in the grooves (21), in which the part The guide includes: i) two vertical grooves (24) in the upper and lower part of the rear opening (19), ii) two internal grooves (21) for the pulley support (23) within a guide piece, characterized in that iii) the cylinder (33) of the pulley (23) has an elliptical surface (23), while the cross section of the cylindrical side walls (32) of the elliptical cylinder (33) of the pulley (23) has a diameter greater than the diameter of any cross section of the cylinder (33), so that some beams of ropes (11a and 11b) can move continuously through the interior of the hole inside the guide piece (15) and between the cylindrical side walls (32), without leaving them (32), and the cylindrical side walls (32) have a thickness such that the internal distance between the surfaces of the walls (32) is less than the length inside the opening of the upper side (17) and lower (18) of the guide piece, so that the ropes move inside of the openings (17 and 18) of the guide pieces (15a-15f) without contacting the inside of the walls of the openings (17 and 18).

Description

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

DESCRIPTION

Crane piece with an internal pulley

The invention relates to the field of mechanics for mosquito net systems with horizontal door movement.

In the current state of the art, these systems use two types of mesh (mosquito net): the plain fabric that is rolled and unwound and the pleated mesh that folds and unfolds. The pleated mesh is folded and deployed by any of the fixed horizontal rails permanently screwed on the top and bottom of the frame, or inside an articulated rail that enters and exits the box system, along with the mesh .

In systems that use pleated mesh, the mesh is folded into folds between two vertical boxes, the retention box and the sliding box.

The entire system resembles a frame, whose two vertical sides serve as a retention box and a sliding box. The retention box is screwed into a vertical frame. Simultaneously, a fixed side rail is screwed into the opposite vertical frame. The sliding box moves parallel between the retention box and the fixed side rail. Two fixed rails, screwed into the upper and lower opening of the frame, respectively, serve as the two horizontal sides. The sliding box moves between the two horizontal aluminum rails in the form of II, upper and lower, with side walls 4 mm high. In this way, the mesh folds and unfolds within the horizontal rails. When the user pulls the sliding box, the pleated mesh unfolds simultaneously; while the user makes the opposite movement, that is, by bringing the sliding case back to its original position, the pleated mesh is folded.

Instead of fixed upper and lower horizontal rails, the system can use two articulated rails inside the retention box and the sliding box. When the user pulls the sliding box to deploy the mosquito net, the two articulated rails bend and leave the upper and lower opening of the retention box, adopting a horizontal position in the upper and lower opening of the frame. As the mosquito net is deployed, its upper and lower termination are always found in the articulated rails. When, on the other hand, the user wishes to fold the mesh and return it to its original place inside the vertical retention box, the user pushes the sliding box towards the original position and simultaneously pushes both articulated rails that fold at their joints and return inside the retention box, to its original position.

The present invention can be applied to pleated mosquito nets, both those that work with a fixed horizontal rail, permanently bolted to the ground, and those that work with an articulated rail. During the operation of the mosquito net system, the pleated mesh folds and unfolds the folds, aided by ropes that cross it horizontally throughout its length. The strings, placed horizontally and equally spaced, stretch and hold the mesh also stretched in place when deployed. They also help the mesh to fold into the folds. All the edges of the ropes, on the side of the retention box, are held by pieces of grna on the plastic shaft. The ropes cross the mesh horizontally and along its entire length and pass through similar pieces of grains with a hole, which are also mounted on a plastic shaft. Then, the entire system "plastic shaft - mesh - ropes - plastic shaft" as an autonomous accessory of the mosquito net, slides along the two vertical rails, and more specifically, the plastic shaft with the fixed ends of the ropes in the pieces of grains, slides through the retention box, which is screwed firmly into the side frame.

On the contrary, the opposite plastic axis, that is, the one with the edges of the rope passing through the holes of the grinding pieces, slides through the sliding box, which moves between the retention box and the fixed vertical side rail. After passing through the pieces of grna, the strings form two groups of equal number of strings, the upper and lower groups:

The strings that pass through the upper part of the mesh form the upper group of strings. The ends of the ropes descend across the sliding box and then form a single beam that horizontally crosses the lower horizontal fixed rail, ending and fixing to the lower end of the fixed lateral rail box.

The strings that pass through the lower part of the mesh form the lower group of strings. The ends of the ropes ascend across the sliding box and then form a single beam that horizontally crosses the upper horizontal fixed rail, ending and fixing on the upper end of the fixed lateral rail box.

At this point, there is a technical problem with each rope that passes through the hole of the workpiece: the continuous opening and closing of the mesh, by folding and unfolding, causes the continuous friction of the ropes on the inner side walls of the hole of the plastic pieces, thus cutting the rope. This destroys the mosquito net, since without ropes the folding and unfolding of the mesh is no longer possible; therefore, the ropes and the mesh have to be replaced.

Such technical problems can occur in all mosquito net systems that use crane parts, for example, in the systems presented in EP 1653038 A1, EP 2157274 A2, Ep 1959090 and JP 8199948.

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

The state of the art is also described in document CA 2 219 946 Alque introduces a gma piece with an internal pulley as well. The present invention modifies the piece of known gma with the pulley of document CA 2 219 946 A1 and introduces a cylindrical surface of the pulley that provides a simple and efficient gma of ropes towards the central part of the cylindrical surface and in the opposite direction to the cylindrical side walls. In addition, documents FR 2 708 661 A1, US 564 682 A and WO 2012/117262 introduce solutions that do not use a gma piece with a pulley, but independent pulleys.

The present invention is a piece of GMA according to claim 1, with a pulley that rotates around an axis just at the height of the center of the hole, through which the rope passes, and with side walls of such thickness that the ropes they do not come into contact with the interior walls of the gma pieces, thus preventing friction. Therefore, the technical problem that causes the cutting of the rope is solved. The advantage of this invention is that the ropes are not cut due to ordinary use and, therefore, the useful life of the product is multiplied, that is, of the entire mosquito net system.

The 10 accompanying drawings that accompany the invention show, in summary, the following:

Drawing 1 illustrates the mosquito net system with a pleated mesh that moves through a channel of a fixed upper and lower horizontal rail, while the bundles of ropes pass in front of the pulleys and in detail, shows a piece of gma with a pulley through which a rope from the lower group passes up (Figure 1a), a piece of gma with a pulley through which the rope from the upper group of ropes (Figure 1b) passes down and a piece of gma of the current state of the art, that is, without pulley, with the end of the rope fixed to it (Figure 1c).

Drawing 2 illustrates the mode of use of the invention when the pleated mesh mosquito net system moves with articulated upper and lower gmas and illustrates in detail, a gma piece with a pulley through which the rope of the rope passes upwards. lower group (Figure 2a), a piece of gma with a pulley through which the rope of the upper group passes down (Figure 2b), with the bundles of ropes passing in front of the pulleys and a piece of gma with pulley , with the end of the rope attached to it (Figure 2c).

Drawing 3 illustrates the accessories inside the gma piece with a pulley (Figure 3a), a front view of the gma piece (Figure 3b), a side view (Figure 3c), a top view (Figure 3d) and a side perspective drawing (Figure 3e).

Drawing 4 illustrates the direction of movement of the pulley and the strings of the upper and lower group while the pleated mesh is deployed.

Drawing 5 illustrates the way in which the strings of the upper and lower group pass through the gma pieces and their direction while the mesh is deployed.

Drawing 6 illustrates the direction of movement of the pulley and the strings of the upper and lower group while the pleated mesh is folded.

Drawing 7 illustrates the way in which the strings of the upper and lower group pass through the gma pieces and their direction while the pleated mesh is folded.

Drawing 8 illustrates the way in which the strings pass through the gma pieces when the invention is applied, according to drawings 1 and 2, and more specifically, the way in which the bundle of strings passes through the gma piece and in front of the pulley, as well as the rope around the pulley, a front view (Figure 8a), a side view (Figure 8b), a top view (Figure 8c) and a perspective view (Figure 8d).

Drawing 9 illustrates an alternative mode for the use of the invention, in which the beams pass behind the pulleys and in detail, a gma piece with a pulley through which a rope of the lower group passes upwards ( Figure 9a), a piece of gma with a pulley through which a rope from the upper string group passes down (Figure 9b) and a piece of gma of the current state of the art, that is, without a pulley, with the edge of the rope fixed on it (Figure 9c).

Drawing 10 illustrates the front view of the alternative use, illustrated in Figure 9, and more specifically, the way in which the string bundle passes through the gma piece and behind the pulley, and the mode in which the rope passes around the pulley, a front view (Figure 10a), a side view (Figure 10b), a top view (Figure 10c) and the gma piece in a perspective view (Figure 10d).

Next, an example of how this invention is applied is described, with a detailed description and with reference to the attached drawings.

As shown in drawings 1, 2, 4, 6, ropes, used to fold and unfold the mesh, cross the pleated mesh horizontally and at equal distances (7). These strings are divided into two groups: the upper group with three strings (1, 2, 3) and the lower group with an equal number of strings (4, 5, 6). In this example, both groups have an equal number of strings. In another application of this invention, however, the number of strings of the two groups may not be the same, although they will always be in a horizontal position.

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

60

As shown in drawing 1, the strings are fixed in reverse, that is, the lower group in the upper space and the upper group in the lower space and more specifically:

The three strings of the lower group (4, 5, 6) cross the mesh (7) horizontally and then join in a beam (11a) that crosses the sliding box (10) vertically upwards around the pulley (8) that is located at the upper end of the sliding box (10). Next, the beam (11a), formed by the three ropes (4, 5, 6), goes inside and horizontally through the upper horizontal rail (12) and is fixed at a point on the top of the fixed vertical side rail (14 ).

Similarly, the three strings of the upper group (1, 2, 3) cross the mesh (7) horizontally and then join in a unified beam (11b) that crosses the sliding box (10) vertically downwards, rotating around the pulley (9) inside the lower fixed horizontal rail (13). Next, the unified beam (11b), consisting of the three strings (1, 2, 3), crosses horizontally through the inside of the lower horizontal rail (13) and is fixed at a point on the bottom of the rail fixed vertical side (14).

As shown in drawings 3 and 8, which illustrate the pulley crane piece (Figure 3a), a front view (3b and 8a), a side view (3c and 8b), a top view (3d and 8c) and a side perspective view (3e and 8d), the grna piece (15) has an internal vacuum chamber with openings facing each other on its four sides: upper (17), lower (18), rear (19) and front with a hole (20), and on the rear side (19) has two vertical grooves (24). It also has two internal grooves (21) to support the pulley (23) within them. The pulley (23) consists of a cylinder (33) with an elliptical surface, with the smallest diameter in the center of its length and with cylindrical side walls (32). The pulley (23) rotates around the horizontal axis (22) and is located in such a position that it provides sufficient space to allow the passage and free movement of all the ropes through the grinding piece (15), both from the side front of it, that is, between the pulley and the hole (20), as from its rear side, that is, between the pulley and the vertical grooves (24).

As shown in Figures 3a, 3d, 8b, 8c and 8d, the cylinder (33) of the pulley (23) has cylindrical walls (32) whose cross section has a diameter larger than the diameter of any cross section of the elliptical cylinder (33), so that the bundles of the ropes (11a and 11b) move continuously between the lateral cylindrical walls (32) of the cylinder (33) of the pulley (23) and do not slide along them. In addition, the lateral cylindrical walls (32) of the pulley cylinder (33) have a thickness such that the internal distance between the surfaces of the walls (32) is less than the length within the opening of the upper side ( 17) and the lower side (18) of the piece of grna (Figures 3d and 8c). Consequently, and since the pulley cylinder (33) has an elliptical shape with the smallest diameter at the center of its length, the bundles of the ropes (11a and 11b) move continuously between the lateral cylindrical walls (32) of the cylinder from the pulley (23) and through the center of the cylinder where the part with the smallest diameter is. In this way, the ropes never come into contact with the side walls of the opening of the upper side (17) and the lower side (18) of the grinding piece (15), or with the inner walls of the holes (20) through which the grna pieces pass and, consequently, do not fray and do not wear out.

Each piece of grna (15) has on the back side (19) lateral vertical grooves (24) from which the ropes (1, 2, 3, 4, 5, 6) pass through the inside of the grna piece. The grooves have an opening smaller than the thickness of the ropes, so that the ropes pass through the inside of the workpiece after being pressed, when the mosquito net system is made and then, during the use of the system and not they leave the piece of grna.

Drawing 8 illustrates in detail the way in which the rope (1) passes around the pulley (23) (Figure 8a), and the way in which the rope bundle (4, 5, 6, beam 11a) passes on the inside of the piece of grna; a front view (Figure 8a), a side view (Figure 8b), a top view (Figure 8c) and a perspective view (Figure 8d).

All the pieces of grna (15a, 15b, 15c, 15d, 15e, 15f) are fixed on a plastic support shaft (25b) inside the sliding box (10) (Drawing 1, figures 1a, 1b and Drawings 5 and 7). As illustrated in drawings 1, 3, 5, 7 and 8, the strings of the lower group (4, 5, 6) have their end fixed in a single starting piece of piece (31), a piece of piece of the current state of the art (Figure 1c), in a plastic support shaft (25a) inside the retention box (30).

As illustrated in drawings 1, 4, 5, 6 and 7, the rope (6) that crosses the mesh (7), at the bottom, crosses the mesh horizontally (7), passes through the hole (20 ) of the workpiece (15f), enters the workpiece and passes around the pulley (23) of the workpiece and from its lower side, upwards. The pulley (23) is located at such a height with respect to the hole (20), that the rope (6) passes through the hole (20) and around the pulley (23) from its lower side, to remain aligned (Figure 1a) and without coming into contact with the inner walls of the hole (20). At the same time, the walls (32) of the pulley prevent the rope (6) from coming into contact with the walls of the upper opening (17) and lower (18) of the piece of crane (15f) (Drawings 4 and 6 ). Next, the rope (6) after passing around the pulley (23) leaves the top opening (17) of the crane piece (15f) and enters the crane piece that is above (15e) from the lower opening (18), exits the upper opening (17), then enters the next piece of crane (15d) that is above from the lower opening (18) and exits the upper opening (17), and so on , thus passes vertically from all openings (18 and 17) of all the following crane pieces that are above (15c, 15b, 15a) to the fixed upper horizontal rail (12).

4

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

60

In exactly the same way, the next string (5) of the lower group crosses the mesh horizontally (7), passes through the hole (20) of the gma piece (15e), enters the gma piece and passes around the pulley (23) of the gma piece and from its lower side, upwards. The pulley (23) is located at such a height with respect to the hole (20), that the rope passes through the hole (20) and around the pulley (23) from its lower side, to remain aligned and without contacting with the internal walls of the hole (20). At the same time, the walls (32) of the pulley prevent the rope (5) from coming into contact with the walls of the upper (17) and lower (18) opening of the gma piece (15e) (Drawings 4-7 ). Next, the rope (5), like the previous rope (6), after passing around the pulley (23), exits the upper opening (17) of the gma piece (15e) and enters the piece of gma that is above (15d) from the lower opening (18), exits the upper opening (17), and thus successively passes vertically from all the openings (18 and 17) of all the following pieces of gma that are above (15c, 15b, 15a) towards the fixed upper horizontal rail (12).

Similarly, the next string (4) of the lower group that crosses the mesh horizontally (7), passes through the hole (20) of the gma piece (15d), enters the gma piece and passes around the pulley (23) of the gma piece and from its lower side, upwards. The pulley (23) is located at such a height with respect to the hole (20), that the rope passes through the hole (20) and around the pulley (23) from its lower side, to remain aligned and without contacting with the internal walls of the hole (20). At the same time, the walls (32) of the pulley prevent the rope (4) from coming into contact with the walls of the upper (17) and lower (18) opening of the gma piece (15d) (Drawings 4-7 ). Next, the rope (4), like the other two ropes (5, 6), after passing around the pulley (23), exits the upper opening (17) of the gma piece (15d) and enters, through the lower opening (18), in the piece of gma that is above (15c). Then, the rope (4) passes vertically, in the same way, from the openings (18 and 17) of all the following gma pieces that are above (15b, 15a) to the fixed upper horizontal rail (12).

The three strings (6, 5, 4) of the lower group end up as a single vertical beam (11a) on the pulley (8), at the upper end of the sliding box (10) (Figures 1, 3, 8a, 8b, 8c and 8d), are wrapped around the box, cross the entire upper horizontal rail (12) and are fixed at a point located at the top of the fixed vertical side rail (14).

Thus, as illustrated in Drawings 5 and 7, the beam (11a) of the strings of the upper group (4, 5, 6) passes vertically from the openings (17 and 18) of the gma pieces (15c, 15b , 15e) and from the side between the pulley (23) and the hole (20), towards the upper horizontal rail (12). The beam moves continuously between the lateral cylindrical walls (32) of the cylinder (33) of the pulley (23) and comes into contact only with the pulleys (23) of the gma pieces (Drawings 5 and 7) from the front side of the pulley, that is, the side between the pulley (23) and the hole (20). Due to the walls (32) of the pulley cylinders (33), the ropes do not come in contact with and, therefore, do not wear out, nor the hole walls (20) when entering the gma pieces, nor the walls of the openings 17) and (18) of the gma pieces when they move during the folding and unfolding of the mesh. Furthermore, due to the walls (32) of the pulley cylinders (33), the ropes do not come into contact with the ropes (1, 2, 3) of the upper group that pass around the pulleys (23) of these pieces of gma (15a, 15b, 15c). Therefore, the strings do not wear out.

The upper group of strings (1, 2, 3) works in the same way and in reverse.

Specifically, as illustrated in Drawings 1, 3, 5, 7 and 8, the strings of the upper group (1, 2, 3) have their end fixed with a simple piece of starting gma (31) (Figure 1c) , a piece of gma of the current state of the art, on a plastic support shaft (25a) inside the retention box (30), in the same way that the strings of the lower group (4, 5, 6) are fixed ), as described above.

As illustrated in Drawings 1, 4, 5, 6 and 7, a rope (1) that crosses the mesh (7) through its upper part, crosses the mesh horizontally (7), passes through the hole (20) of the gma piece (15a), enters the gma piece and passes around the pulley (23) of the gma piece and from its upper side, downwards. The pulley (23) is located at such a height with respect to the hole (20), that the rope (1) when passing through the hole (20) and around the pulley (23) from its upper side, remains aligned (Figure 1b) and without contacting the inner walls of the hole (20). At the same time, the walls (32) of the pulley prevent the rope (1) from coming into contact with the walls of the upper (17) and lower (18) opening of the gma piece (15a) (Drawings 4 and 6 ). Next, the rope (1), after passing around the pulley (23), leaves the lower opening (18) of the gma piece (15a) and enters the lower gma piece (15b) from the opening upper (17), leaves the lower opening (18), then enters the next piece of gma (15c) that is below from the upper opening (17) and leaves the lower opening (18), and thus successively, thus passes vertically from all openings (17 and 18) of all subsequent subsequent gma pieces (15d, 15e, 15f) to the fixed lower horizontal rail (13).

In exactly the same way, the next string (2) of the upper group passes through the mesh (7), passes through the hole (20) of the gma piece (15b), enters the gma piece and passes around the pulley (23) of the gma piece and from its upper side, down. The pulley (23) is located at such a height with respect to the hole (20), that the rope when passing through the hole (20) and around the pulley (23) from its upper side, remains aligned and without contacting with the internal walls of the hole (20). At the same time, the walls (32) of the pulley prevent the rope (2) from coming into contact with the walls of the upper (17) and lower (18) opening of the gma piece (15b) (Drawings 4-7 ). Then the string (2), like the previous string (1), after passing

5

10

fifteen

twenty

25

30

35

40

Four. Five

fifty

55

60

around the pulley (23), it exits the lower opening (18) of the gma piece (15b) and enters the lower gma piece (15c) from the upper opening (17) and thus successively passes in that way vertically from all openings (17 and 18) of all the following gma pieces that are below (15d, 15e, 15f) towards the fixed lower horizontal rafl (13).

Similarly, the next rope (3) of the upper group that crosses the mesh horizontally (7) passes through the hole (20) of the gma piece (15c), enters the gma piece and passes around the pulley (23) of the piece of gma and from its upper side, down. The pulley (23) is located at such a height with respect to the hole (20), that the rope, when passing through the hole (20) and around the pulley (23) from its upper side, remains aligned and not placed in contact with the inner walls of the hole (20). At the same time, the walls (32) of the pulley prevent the rope (4) from coming into contact with the walls of the upper (17) and lower (18) opening of the gma piece (15c) (Drawings 4-7 ). Next, the rope (3), like the other two ropes (2, 1), after passing around the pulley (23), leaves the lower opening (18) of the gma piece (15c), it enters the upper opening (17) of the next rear gma piece (15d). Next, the rope (3) passes vertically, in the same way, from the openings (17 and 18) of all the following gma pieces down (15e, 15f), to the fixed lower horizontal rail (13).

The three strings (1, 2, 3) of the upper group end up as a single vertical beam (11b) on the pulley (9), at the lower end of the sliding box (10) (Figures 8a, 8b, 8c and 8d) , are wrapped around the box, cross the entire lower horizontal rail (13) and are fixed at a point located at the bottom of the fixed vertical side rail (14) (Drawing 1).

Thus, as illustrated in Drawings 5 and 7, the beam (11b) of the strings of the upper group (1, 2, 3) passes vertically from the openings (17 and 18) of the gma pieces (15d, 15e, 15f) and from the side between the pulley (23) and the hole (20), towards the lower horizontal rail (13). The beam moves continuously between the lateral cylindrical walls (32) of the cylinder (33) of the pulley (23) and comes into contact only with the pulleys (23) of the gma pieces (Drawings 5 and 7) from the front side of the pulley, that is, the side between the pulley (23) and the holes (20). Due to the walls (32) of the pulley cylinders (33), the ropes do not come into contact with and, therefore, do not wear away the hole walls (20) when entering the gma pieces, nor the walls of the openings (17) and (18) of the gma pieces when they move during the folding and unfolding of the mesh. Furthermore, due to the walls (32) of the pulley cylinders (33), the ropes do not come into contact with the ropes (4, 5, 6) of the lower group that pass around the pulleys (23) of these pieces of gma (15d, 15e, 15f). Therefore, the strings do not wear out.

Drawings 4 and 5 illustrate the direction of the pulley (23) and the movement of the ropes when the mesh is deployed. Drawings 6 and 7 illustrate the direction of the pulley (23) and the movement of the ropes when the mesh is folded.

Therefore, when the mesh (7) is deployed (Drawings 4 and 5), the sliding box (10) moves towards the fixed vertical side rail (14). This movement causes the strings of the lower group (4, 5, 6) to rotate around the pulleys (23) of the respective gma pieces (15d, 15e, 15f) counterclockwise, while the upper group ropes (1, 2, 3) rotate around the pulleys (23) of the respective gma pieces (15a, 15b, 15c) clockwise, and therefore the mesh (7) is unfolds without the strings fraying or wear due to the gma piece pulleys (23).

On the contrary, when the mesh (7) is folded (Drawings 6 and 7), the sliding box (10) moves towards the retention box (30). This movement causes the strings of the lower group (4, 5, 6) to rotate around the pulleys (23) of the respective gma pieces (15d, 15e, 15f) clockwise, while the ropes of the upper group (1, 2, 3) revolve around the pulleys (23) of the respective gma pieces (15a, 15b, 15c) counterclockwise, so that the mesh (7) is folds without the strings fraying or wear due to the gma piece pulleys (23).

An alternative application of the invention is illustrated in Drawings 9 and 10; the invention is the same and works in exactly the same way when the beams (11a) and (11b) of the ropes pass from the rear side of the pulley, that is, the side on which the grooves (24) of the gma piece (15) and not the front side of the pulley, that is, the side between the pulley and the opening (20).

Another alternative application of the invention is illustrated in Drawing 2, when the mosquito net system has, instead of the two fixed upper (12) and lower (13) horizontal rails, an upper (26) and lower (27) articulated rail (Drawing 2); in this case, the ropes do not cross the horizontal rails (26 and 27) along their entire length and are not fixed on the fixed vertical side rail (14). In this case, the strings cross along the mesh (7) horizontally, at equal distances between sf and alternatively, forming two sets (set 1, 3, 5 and set 2, 4, 6). The strings of the first set (1, 3, 5) have the shaft (25b) at the end of the mesh (7) as a common starting point, inside the sliding box (10) that ends and is fixed at the upper end (28) of the upper articulated rail (26), while the ropes of the second set (2, 4, 6) have as common starting point the shaft (25a) at the end of the mesh (7) inside the box retention (30) that ends and is fixed at the lower end (29) of the lower articulated rail (27). In this case, at the points where the strings begin (1, 2, 3, 4, 5, 6) pieces of starting gma (31) are used for fixing, the current state of the art, and these pieces They are alternately located on the two axes, the shaft (25b) inside the sliding box (10) and the shaft (25a) inside the retention box (30). Next, each rope passes horizontally through the mesh (7) and the other end passes through

6

the gma piece having a pulley (15), in accordance with the present invention, and these gma pieces are also placed alternately on the two axes, the shaft (25b) inside the sliding box (10) and the shaft (25a) inside the retention box (30), unlike the starting gma pieces (31). This type of mosquito net systems require the free movement of the ropes, on the side of the retention box (30), as well as on the sliding box 5 (10). This free movement is maximized due to the gma pieces (15) of this invention, which eliminate friction

of the ropes and facilitate the opening and closing of the mosquito net.

The present invention is applied in mosquito net systems that have a pleated mesh and move horizontally, that work well with a fixed horizontal rail that is permanently bolted to the ground, or with an articulated rail.

10

Claims (3)

5 10 fifteen twenty 25 1. Piece for the support of the ropes of a pleated mosquito net, with a hollow chamber and openings facing its four sides, an upper opening (17), a lower opening (18), a front opening with hole (20 ) and a rear opening (19), a pulley (23) consisting of a cylinder (33) with cylindrical side walls (32), which rotates around an axis (22) mounted in the grooves (21), in which the piece of crane comprises: i) two vertical slits (24) in the upper and lower part of the rear opening (19), ii) two internal grooves (21) for the pulley support (23) within a piece of grind, characterized in that iii) the cylinder (33) of the pulley (23) has an elliptical surface (23), while the cross section of the cylindrical side walls (32) of the elliptical cylinder (33) of the pulley (23) has a larger diameter that the diameter of any cross section of the cylinder (33), so that a bundle of ropes (11a and 11b) can move continuously through the interior of the hole inside the piece of grind (15) and between the cylindrical side walls (32 ), without leaving them (32), and the cylindrical side walls (32) have a thickness such that the internal distance between the surfaces of the walls (32) is less than the length within the opening of the upper side (17) and bottom (18) of the workpiece, so that the ropes move inside the openings (17 and 18) of the workpiece (15a-15f) without contacting the inner part of the walls of the openings (17 and 18). 2. A piece of grating for the support of the ropes of the pleated mosquito net according to claim 1, characterized in that the pulley (23) with the shaft (22) is placed horizontally in the two internal grooves (21) of the piece of grna (15). 3. Grinding piece for the support of the ropes of the pleated mosquito net according to claims 1 to 2, characterized in that the pulley (23) is placed inside the grinding piece (15) in a position such that its axis (22) is oriented vertically with respect to the rope (1-6) that enters horizontally in the workpiece and at a height such that the rope passes through the center of the hole (20) of the workpiece ( 15) and continues to wind in the elliptical cylinder (33) in half its length, where the diameter is the smallest, remaining in a horizontal position and without contacting the side walls of the hole (20), from the center of which it enters the piece of grna (15).