ES2264909A1 - Swiveling nozzle for unclog hoses description - Google Patents

Abstract

The invention relates to a swiveling nozzle for unclog hoses particularly designed for accessing pipes with interruptions in their course. It has a head (1 ), integral with a swiveling spherical segment (2) inside a spherical bushing (3) provided with a groove (4) in which a neck (6) connecting the spherical segment (2) with the head (1 ) works, and said spherical segment (2) being provided close to its swivel center (8), coinciding with its geometric center, with a guiding element (9) acted on by transmission means from an actuator (13) which in turn can axially move inside a cylindrical bushing (5) integral with the spherical bushing (3) opposite to the head (1), against the tension of a spring (14) and when the water under pressure accesses the nozzle. In each maneuver in which water is supplied to the nozzle the orientation of the head (1 ) thus changes.

Description

Adjustable nozzle for hoses Unclog

Object of the invention

The present invention relates to a nozzle for unblocking hoses, of the type that incorporate a head, with a plurality of holes for water outlet to pressure, which acts simultaneously as a washing medium and as means of advance for the nozzle; nozzle of those intended to finish off a hose that supplies water under pressure, for the unblocking of pipes, nozzle that by the effect of the water pressure itself that arrives at the same advances along the pipe producing the cleaning and consequent unblocking of it.

The object of the invention is to achieve a adjustable nozzle, which facilitates its own change of direction to the length of the pipe, specifically when there is a lateral bypass forming an orthogonal or with any other angle, so that this change in the direction of advance of the nozzle is carried out from the outside and without more than act on the water supply valve.

The invention is therefore applicable in the scope of cleaning equipment of all types of networks wastewater evacuation.

Background of the invention

Current systems for unblocking pipes, are based on the use of a nozzle, usually in spherical cap shape, which are conveniently fixed to the free end of the corresponding feed hose water, said nozzles being provided with one or more holes in their front or polar area, for dirt removal with jet water in the direction of movement, and counting on a series of latero-posterior, oblique and divergent exits, that fulfill a double function, on the one hand they generate the advance of the hose and on the other they give off debris from the walls of the pipe, which are conveniently dragged.

These nozzles, with adequate functionality when it comes to cleaning a single pipe, with any trajectory, present important problems when the jam is located on a branch of said pipe, which forms an elbow with it, and consequently the nozzle must make a sudden change of direction, or also when accessing a box where the guidance effect produced by the own is interrupted
pipeline.

In many occasions the fork or the casket they are not accessible, because they are covered with tiles or with any other type of lining material, to meet many depth, because they are located inside false ceilings accessible or detachable, etc. So in these cases you it is essential to "break" to access the point where the nozzle must be helped manually to its routing or change of address.

Obviously these maneuvers involve a considerable additional work of the operators, which in the majority of cases is increased by ignorance of the trajectory of the pipes because they are hidden and not have plans of them, with the consequent impact that This involves both direct and indirect costs shopping centers or workplaces, where it is necessary interrupt the activity during the operations of unblocking

Description of the invention

The adjustable nozzle that the invention proposes solves the problem fully satisfactorily previously exposed allowing its orientation change from outside, with no more than acting on the supply valve of pressure cleaning water.

To do this and more specifically the head of the nozzle that the invention proposes receives jointly and severally spherical segment, tightly housed within a socket also spherical, spherical bushing which in turn is supportive, in opposition to the aforementioned head, to a cylindrical bushing attachable to the hose end. The said spherical segment is susceptible of turning on its axis of rotation, within the spherical bush, with a movement guided by a groove of said bushing spherical, which is crossed by a neck that relates the segment spherical with the head. The spherical segment incorporates, in the close to its center of tilt, a guiding element on which transmission means act from an actuator established within the cylindrical bushing and movable by Water pressure against a spring. This way every time that the water pressure is applied the guiding element changes from position by dragging the spherical segment, which scales from to each other end of the groove of the bushing, varying the head orientation at a planned angle, defined by the length of said slot.

The operation is as follows: at the moment in which the water pressure is applied, by opening the corresponding valve, the mechanism will go through the guiding element to its other limit position, out of date angularly with respect to the first in a given magnitude by the angular width of the groove of the spherical bushing. When the water supply valve is closed the pressure will cease and the nozzle head will maintain the limit position in which it find. By applying pressure to the nozzle again, the head it will turn until it reaches its other limit position, giving the whole of a new direction of movement. If you close the water supply valve, the head will keep the limit position where you are. This operating cycle is repeat indefinitely, changing the orientation head every once the water pressure is applied by opening the valve water supply.

To limit an unwanted turning movement of the nozzle head, for example due to fluctuations or fluctuations in water pressure or possible momentary cuts of the supply, the movement of the nozzle can be limited restricting it through a clipping mechanism in each of the two extreme positions, so that each time it is applied water pressure, it must be high enough to unclip the head and change orientation. This way you avoid unwanted orientation changes.

These essential characteristics of the nozzle adjustable that the invention proposes, which are included in the first claim, they are complemented by a series of additional or complementary characteristics, which appear in the dependent claims, which further define different embodiments.

Description of the drawings

To complement the description that is being performing and in order to help a better understanding of the characteristics of the invention, according to a preferred example of practical realization of it, is accompanied as part member of that description, a set of drawings where with illustrative and non-limiting nature, what has been represented next:

Figure 1.- Shows, according to a representation Schematic elevation and diametral section, an adjustable nozzle for unclogging hoses made in accordance with the purpose of The present invention.

Figure 2.- Shows, according to a representation three-dimensional, spherical segment and nozzle cam adjustable of figure 1.

Figure 3.- Shows, according to a representation similar to that of figure 1, the four phases corresponding to a operating cycle of the adjustable nozzle of said figure 1.

Figure 4.- Shows, according to a representation similar to that of figure 1, a variant embodiment of the nozzle, in which the actuation means of the element change Guided

Figure 5.- Shows a plan view and in perspective of the cap that participates in the mentioned means of motion transmission of the nozzle of the previous figure.

Figure 6.- Shows, according to a representation similar to that of figure 4, the four phases corresponding to a operating cycle of the adjustable nozzle of said figure 4.

Figure 7.- Shows, according to a representation similar to that of figures 1 and 4, another variant embodiment of The adjustable nozzle.

Figure 8.- Shows a groove development perimeter of the wheel that participates in the nozzle of the figure previous as a guiding element.

Figure 9.- Shows, according to a representation similar to that of figure 7, the four phases corresponding to a operating cycle of the adjustable nozzle of said figure 7.

Figure 10.- Shows, according to a representation similar to that of figures 1, 4 and 7, another variant embodiment of the adjustable nozzle.

Figure 11.- Shows an enlarged detail of the slotted part that participates in the adjustable nozzle of the figure 10 as a guiding element.

Figure 12.- Shows, according to a representation similar to that of figure 10, the four phases corresponding to an operating cycle of the adjustable nozzle of said figure 10.

Preferred Embodiment of the Invention

In view of the figures outlined you can be observed as the orientable nozzle that the invention proposes incorporates a head (1), itself conventional, usually in spherical cap shape, with the classic exit holes of water, head (1) to which it is integral, preferably by a threaded joint (1 '), a spherical segment (2) that plays in the breast of an equally spherical bushing, provided with a groove (4) and which through its area opposite the head (1) is in turn fixed to a cylindrical bushing (5) attachable to the end of the hose water input. The slot opening (4) made in the spherical bushing (3) normally covers an angle equal to or less than 90º.

The spherical segment (2) is provided with a neck (6) through which it joins through the thread (1 ') to the head (1), said neck (6) playing in the groove (4) of the spherical bushing (3), groove whose length determines the angle maximum tilt for the spherical segment (2) and consequently for the head (1). For its part the cap spherical (3) extends in turn in opposition to the head (1) in a threaded neck (7) through which it attaches to the bushing cylindrical (5).

In the example of practical realization of the Figure 1 spherical segment (2) incorporates, in correspondence with its center of rotation (8), coinciding with its geometric center, a cam (9) as a guiding element that constitutes the bottom of a slot (11) in which one of the ends of a rocker plays (10), through a small roller (15). The rocker (10) by its other end penetrates the cylindrical bushing (5) and relates with the actuator (13) through a slot (12). Said actuator (13) consists of a cylinder, of diameter substantially smaller than the cap (5), which leaves a perimetral passage for water with with respect to the cylindrical bushing (5) and that moves axially within the latter. The actuator (13) is conveniently guided against the tension of a spring (14) that tends to said actuator (13) rests on the strangulated mouth (16) of the cylindrical bushing (5) in rest situation, blocking the passage of water. The actuator (13) moves against the spring (14) by the water thrust when pressure is applied.

In Figure 2 it can be seen, according to a three-dimensional representation, the spherical segment (2) and the cam (9) of the adjustable nozzle of Figure 1.

According to this structuring and how it follows from the observation of Figure 3, in a first phase A operation of the adjustable nozzle, specifically in a phase of rest where the water inlet valve is closed, the spring (14) is extended, the actuator (13) rests on the strangulated mouth (16) of the cylindrical bushing (5), the rocker (10) is separated from cam (9), and the assembly constituted by the spherical segment (2) and the head (1) is align with the hose in one direction I. When opening the valve water passage and as shown in phase B of said figure 3, the roller (15) of the rocker arm (10) contacts the cam (9) by the left side and force said set spherical head-segment (1,2) to swing at length of the groove (4) to the expected limit situation in which the head (1) is oriented in direction II. In phase C of said figure, by interrupting the water supply again the actuator (13) returns, due to the spring (14), to the position of phase A rest, but head (1) still maintains the layered position of phase B, oriented in direction II, of so that when water circulates again through the hose, as represents in phase D, the rocker (10) meets the opposite slope of the cam (9), forcing the latter to swing in the opposite direction, that is, forcing the head (1) to occupy again the axial position of phase A, and being able to repeat this cycle indefinitely.

In the variant embodiment of Figure 4, have used the same references as in the previous case to reference the same elements, and more specifically the nozzle adjustable incorporates the same head (1), the same segment spherical (2), the same spherical bushing (3) with groove (4) and the same cylindrical bushing (5) with actuator, but with the exception that in the present case the guiding element materializes in a fin (17), preferably curved to facilitate rotation, tilting with the spherical segment itself (2) and with the head (1), the fin (17) facing the actuator, materialized this in a disc (18) provided with a side hole (22), disc which tends to retract due to the tension of a spring (19) established between said disk (18) and a support (20) fixed to the cylindrical bushing (5) and allowing the free passage of water to its through.

The cylindrical bushing (5) incorporates, in its inner wall, helical guide paths (21), diametrically opposite, that force the mentioned disc (18) to a movement 180º swivel on each axial displacement of said disk (18) by effect of the spring (19) when the water pressure ceases, and paths vertical guides (21 '), diametrically opposite, that guide the disc (18) in an axial direction movement, according to the direction of the cylindrical bushing shaft (5), when the pressure of Water. When the water pressure ceases, the spring forces the disc (18) to follow the path marked by the helical guides (21) due to a chamfer finish at the upper end of the vertical guides (21 '), termination that places the disc (18) in a favorable orientation to follow the way down marked by helical guides (21). Both helical guides and verticals (21,21 ') are especially visible in the details of Figure 5.

The hole (22) for water passage is alternatively facing one or the other end of the fin (17), according to the phase you are in, as will be explained in the Figure 6. Each time the water pressure is applied, the jet of water passing through the hole (22) generates a pressure on the fin (17) causing alternative tilting in one or the other sense of it, and consequently of the head (1).

According to this structuring and as it is shows in phase A of Figure 6, at rest, the head (1) is aligned with the axis of the cylindrical bushing (5) oriented in the direction I, the hole (22) of the disc (18) of the actuator faces the most retracted end of the fin (17), at the same time that said disk (18) also adopts the position of maximum retraction, due to the spring (19). When the valve opens  water supply, the jet that passes through the hole (22) impacts on the mentioned end of the fin (17), and forces it to a tilting movement on its axis of rotation (8) adopting the set the position shown in phase B of said figure 6, in the that the axis of the head (1) forms a predetermined angle with the axis of the cylindrical bushing (5), according to a direction II. In this position and when interrupting the water supply, the spring (19) is recover elastically by dragging the disk (18) and forcing to the latter, through the helical guides (21), to turn 180º, so that the hole (22) changes position and remains facing the other end of the fin (17), as shown in phase C of figure 6, the assembly being in conditions of that, when receiving the water again the nozzle and when the impact occurs of the jet on the opposite end of the fin (17) to that of the case above, there is a new tilting of the head (1), and back to its first position, direction I, as it shown in phase D of figure 6.

A third embodiment of the nozzle orientable appears in Figures 7 to 9, where as in the case above the same numerical references have been used to identify the components that match the other two previous embodiments, and which are those already mentioned in the second case.

In this third embodiment the element of guided materializes in a corrugated wheel (23), mounted with freedom of rotation on a horizontal axis (24) integral with spherical bushing (3). The wheel is provided with a groove perimeter (25) that acts as a guiding element and that appears shown in development in figure 8, in which a busty (26) plays in solidarity with the spherical segment (2). Said wheel (23) is rotatably driven by the actuator (28) through a connecting rod (27) integral to it, connecting rod eccentrically the wheel (23) with the actuator (28), the actuator (28) being movable inside the cylindrical bushing (5) due to the the water flow and against the tension of a spring (29), of so that in the absence of water pressure the spring (29) tends to move the actuator (28) towards a support limit situation on the strangulated mouth (16 ') of the cylindrical bushing, and so that in each axial displacement of the actuator (28) the connecting rod (27) gives the wheel (23) a quarter turn, which by the shape of the perimeter groove (25) in turn causes the tilt alternative of the head (1) each time the pressure of Water.

In this way and from the situation of rest shown in phase A of Figure 9, in which it does not arrive water to the nozzle and in which the spring (29) is distended, of so that the actuator rests on the throttle (16 ') of the mouth of the cylindrical bushing (5), closing the passage of water, and in which the head (1) is aligned coaxially with said cylindrical bushing (5) according to a direction I. When it occurs the opening of the valve and water supply to the hose, the water drags the actuator (28) against the spring (29), and said actuator (28) acts on the connecting rod (27) that supplies the wheel (23) a quarter turn, which brings with it that the groove perimeter (25) of said wheel (23) swing the assembly constituted by the spherical segment (2) and the head (1) towards the another boundary situation defined by the groove (4), oriented in the address II, as shown in phase B of Figure 9. A new interruption in the water supply results in a arrangement for the mechanism as shown in phase C of the Figure 9, and the new water feed makes the mechanism return to the initial coaxial alignment position between the head and cylindrical bushing, according to a direction I, such as it is shown in phase D of said figure.

Another possibility of practical realization of the adjustable nozzle is the one shown in Figures 10 to 12, in which the structure is repeated again and mostly of the nozzle, having used the same numerical references for the identification of parts or parts of matching pieces. The guiding element in this case is it materializes in a slotted trapezoid piece (32), provided with two side slots (33), connected to each other, in nearby portions at its ends, through two other intermediate and cross grooves (3. 4). Said piece has a plurality of gates (35), each with a torsion spring to return to its position of repose. Two gates are located at the intersection of the two intermediate slots (34) and a gate in each of the other intersections The part is shown in detail in Figure 11 grooved (32), with its lateral grooves (33) and crossed (34) and gates (35). In the slots (33, 34) plays a busty (31) that top off the upper end of a movable bar (30) axially within the cylindrical bushing (5) and integral with a actuator (36) that also plays axially within said cylindrical bushing (5) movable by the water stream in against the tension of a spring (37) coaxially mounted on the  bar (30). In the absence of water pressure the spring (37) tends to move the actuator (36) towards a support limit situation on the strangulated mouth (16 '') of the cylindrical bushing. The resting position of the gates (35) is shown in strokes continuous, while in dashed lines the position of said gates (35) when they are opened by the passage of the stud (31). Arranged in the manner reflected in Figure 11, the gates (35) force the busty (31) to follow the paths reflected in the different phases A, B, C and D of Figure 12.

In this case and as the Figure shows 12, each time the actuator (36) changes position, as a result of water flow or by effect of the spring (37), the bar (30) ascends or descends, causing in each upward movement the tilt of the head (1) in the opposite direction to the previous one, while said head maintains the position in each movement of descent, but getting exactly the same as in the cases earlier than, by a simple control over the valve water supply, the orientation of the nozzle.

A phase of Figure 12 shows a resting situation, oriented the head in direction I and with the spring (37) relaxed. In phase B the water pressure is applied, which exerts an effort that causes the displacement of the actuator (36) and consequently of the bar (30) according to the direction of the axis of the cylindrical bushing (5). Thanks to the situation in rest, by action of the spring that incorporates, of the gate (35) located in the lower left corner, the stud (31) of the bar (30) moves with respect to the piece (32) by one of the cross slots (34) to the upper right point, which generates the rotation of the head (1), oriented according to a address II, as shown in phase B. In phase C of said figure 12, when the water stops acting, the situation in resting the upper right hatch forces the pin (31) to follow the side groove (33) to the lower right point, with it does not generate a rotation of the head (1). Finally, when returning to apply water pressure, in phase D, the pin (31) follows the path of one of the intermediate slots (34) until reaching the upper left point, which generates a rotation of the head (1) that it is oriented in the initial position, according to address I.

Claims (6)

1. Adjustable nozzle for unblocking hoses, of the type that incorporate a head (1), with a plurality of holes for pressurized water outlet, which acts simultaneously as a washing means and as a means of advance for the nozzle, characterized because said head (1) welcomes a spherical segment (2), housed tightly within a spherical bushing (3), spherical bushing (3) which in turn is integral, as opposed to said head (1 ), to a cylindrical bushing (5) attachable to the end of the hose, it being provided that the spherical segment (2) is capable of rotating on its axis of rotation (8) within the spherical bushing (3), with a movement guided by a groove (4) of said spherical bush (3), crossed by a neck (6) that relates the spherical segment (2) with the head (1), incorporating said spherical segment (2), in the vicinity of its axis of rotation (8), a guiding element (9-17-23- 32) on which transmission means act from an actuator (13-18-28-36) established within the cylindrical bushing (5), actuator movable by the water pressure against a spring (14-19-29 -37), all this in such a way that each time the water pressure is applied, the guide element (9-17-23-32) changes position by dragging the spherical segment, which swings from one end of the groove to the other. (4), varying the orientation of the head (1) by an expected angle, defined by the length of said groove (4). 2. Adjustable nozzle for unclogging hoses according to claim 1, characterized in that the guiding element is embodied in a cam (9) that constitutes the bottom of a groove (11) in which one of the ends of a rocker (10) plays , through a small roller (15), rocker (10) that at its other end penetrates the cylindrical bushing (5) and relates to the actuator (13) through a groove (12), said actuator materializing ( 13) in a cylinder that leaves a perimeter passage for water with respect to the cylindrical bushing (5) and that moves axially within the latter conveniently guided against the tension of a spring (14) which tends to have said actuator (13) rest on the strangled mouth (16) of the cylindrical bushing (5) in a resting position, blocking the passage of water, and against whose spring (14) the actuator travels by the thrust of the water when applied Pressure. 3. Adjustable nozzle for unclogging hoses according to claim 1, characterized in that the guiding element is embodied in a fin (17), tilting with the spherical segment itself (2) and with the head (1), fin that faces the actuator , materialized in a disk (18) provided with a side hole (22), retractable disk against the tension of a spring (19) resting on a support (20) fixed to the cylindrical bushing (5) and allowing the passage of the water therethrough, incorporating said cylindrical bushing (5), in its inner wall, two helical guides (21) that force said disk (18) to a 180 ° rotating movement in each axial displacement of said disk (18) by effect of the spring (19) when the water pressure ceases, and diametrically opposite vertical guides (21 ') that guide the disk (18) in an axial direction movement when the water pressure is applied, all in such a way that the water hole (22) it is alternately facing one or the other end of the fin (17), and so that each time the water pressure is applied, the water jet passing through the hole (22) generates a pressure on the fin (17 ) causing alternative tilting in one or the other direction thereof, and consequently of the head (1). 4. Adjustable nozzle for unclogging hoses according to claim 1, characterized in that the guiding element is embodied in a grooved wheel (23), mounted with freedom of rotation on a horizontal axis (24) integral with the spherical bushing (3), wheel provided of a perimeter groove (25) that acts as a guiding element, in which a stud (26) integral with the spherical segment (2) plays, said wheel (23) being rotatably driven by the actuator (28) through a connecting rod (27) integral thereto, actuator (28) movable within the cylindrical bushing (5), due to the flow of water and against the tension of a spring (29), so that in the absence of water pressure the spring (29) tends to move the actuator (28) towards a limiting support situation on the strangulated mouth (16 ') of the cylindrical bushing, and so that in each axial displacement of the actuator (28) the connecting rod ( 27) supplies the wheel (23) with a quarter of turn, which by the shape of the perimeter groove (25) in turn causes the alternative tilting of the head (1) each time the water pressure is applied. 5. Adjustable nozzle for unclogging hoses according to claim 1, characterized in that the guiding element is embodied in a grooved part (32), provided with two lateral grooves (33), connected to each other, in portions close to their ends, by other two intermediate and crossed grooves (34), said part having a plurality of gates (35), each with a torsion spring to return to its resting position, two gates being located at the intersection of the two intermediate grooves (34 ) and a gate at each of the other intersections, matching in the grooves (33, 34) a stud (31) that ends the upper end of a bar (30) axially movable in the bosom of the cylindrical bushing (5) and in solidarity with an actuator (36) that also plays axially within said cylindrical bushing (5) movable by the water current against the tension of a spring (37) coaxially mounted on the bar (30), so that in the absence of water pressure, the spring (37) tends to move the actuator (36) towards a boundary position of support on the strangulated mouth (16 '') of the cylindrical bushing. 6. Adjustable nozzle for unclogging hoses according to any of the preceding claims, characterized in that the opening of the groove (4) made in the spherical bushing (3) covers an angle equal to or less than 90 °.