RU2527780C1 - Sprinkler device - Google Patents

Abstract

FIELD: agriculture.SUBSTANCE: sprinkling device comprises an inlet for water and a sprinkler head forming an outlet for water, mounted with the ability of rotation relative to the main housing. Rotation of the sprinkler head is carried out by means of transmission of the sprinkler device, which is actuated by the rotating turbine with blades. The driving flow of water passes through the turbine, which forms at least a part of the total flow of water passing from the water inlet to the water outlet. The turbine is made with the ability of rotation in two opposite directions of rotation. For each direction of rotation one of two feeding channels is provided, each of which is provided with at least one inlet nozzle which determines the direction of running on. Using the switching device located downstream of both feeding channels the ability is provided to connect choosingly one of both feeding channels to the inlet for water. The path of the water passage is made optimally on hydrodynamics and with small twists for the flow passage. The feeding channel has a diversion of direction between the first part of the feeding channel, at least predominantly parallel to the turbine axis, and the second part of the channel extending substantially in the plane of turbine blades radially outwardly of the turbine blades. In the area of this diversion of direction the feeding channel is limited by the first outer wall and the first inner wall. The outer wall has a continuously curved passage free from kinks. The third part of the channel ends at the inlet nozzle, extends through an arc, at least partially around the turbine and tapers steadily. The third part of the channel has in the circumferential direction a continuously curved passage free from kinks in the form of an arc. The flow passage path extends from the inlet nozzle lying radially outwardly of the blades. The blades form a ring around the inner space. The nozzle is inclined at an angle of running on less than 45° relative to the tangent to the turbine. The path also passes through the lumen having at the radially inner ends of the blades between the adjacent blades, radially to the inner space. The guiding surfaces of the blades loaded by the flow from the inlet nozzle pass concavely curved and at an angle of running on, inclined relative to the radial line and in the direction opposite to the corresponding direction of rotation, pass to the inner space.EFFECT: improved performance of start-up at low costs.16 cl, 5 dwg

Description

The invention relates to a sprinkler device

Sprinkling devices as garden irrigation devices usually have a sprinkler head with nozzle system forming a water outlet and mounted to rotate about a rotary axis relative to the main body containing the water inlet. In sector irrigation devices, the rotary axis is usually oriented vertically, in quadrangular irrigation devices - horizontally. The rotation of the sprinkler head is usually carried out by means of the transmission of the sprinkler device, which is driven by a turbine wheel. To switch the direction of the pivoting movement between two rearranged limits of the angle of rotation, it is preferably possible to rotate the turbine with switching in two opposite directions of rotation, for which two separate supply channels and a switching device located downstream of the channels are provided for the driving water flow, which, when switching, connects one of inlet channels with water inlet. The water flow from the inlet to the exhaust device flows at least partially as a drive water stream through the turbine and usually as a bypass water stream through a spring-loaded valve, while the bypass water stream is in most cases larger than the drive water stream. Such systems are well known.

Such an irrigation device with a turbine driven by a stream of water is known from EP 0 489 679 A1. Separate turbine blades form pocket-shaped hollow spaces that open with narrow radial slots to a hollow space surrounded by a ring of turbine blades. The two inlet channels pass their first round sections parallel to the turbine axis from the switching device upwards and enter the narrow second sections that arcuate in the form of opposite lying angular segments of the turbine. Several tapering nozzle channels depart from the second sections at an angle in the direction of the turbine.

The disadvantage of such irrigation devices is that the force acting on the turbine due to the driving water flow is only small and therefore there is a danger that the turbine does not start to rotate when it is restarted or during one of the many switching processes. Since irrigation devices for watering gardens should be cheap to manufacture, design options are limited.

The basis of the present invention is the creation of a sprinkler device with a turbine-driven transmission of a sprinkler device, in which starting characteristics are further improved at low cost.

The solutions according to the invention are indicated in an independent claim. The dependent claims contain preferred embodiments and modifications of the invention.

It has been found that measures taken in accordance with the invention significantly improve the properties of the path of the drive water flow. In particular, the applicants have found that due to the proposed measures, a reduction in the formation of vortices can be achieved and due to this, the energy losses of the drive water flow can be significantly reduced, so that a higher proportion of the energy is generated by the forces acting on the turbine, which leads to a higher starting torque the moment.

The first significant improvement is achieved by changing the shape of the deflecting zone in which the supply channel extends from the first channel section with a stream substantially parallel to the turbine axis to the second channel section, while the flow direction of the second channel section extends substantially in a plane lying perpendicular to the turbine axis. The second section of the channel preferably passes in the form of an arc around the space in which the turbine is located.

The deflecting zone is made favorable for flow and with small vortices due to the fact that at least one limiting inlet channel in the deviation zone relative to the change in the direction of flow of the outer band of the channel, the outer wall is curved. An imaginary axis of deviation can be adopted to change the direction of flow. The first outer wall is, relative to such an axis of deflection, lying radially outside the restriction of the supply channel in the deflection zone. The radius of curvature of the first outer wall may vary during the deflection and is preferably not less than 30%, in particular not less than 60% of the height of the inlet channel in the deflection zone. As the height of the inlet channel, which can vary during the deflection, the corresponding smallest distance of the outer wall from the limiting inlet channel radially inside the first inner wall is taken, while the cross-section of the inlet channel in the deviation zone should be based on the center of gravity of the surface the cross section of the inlet channel in the deviation zone.

Preferably, the first inner wall of the inlet channel extends in the deflection zone without kinks and steps, in particular with monotonous bending, while the possibly varying radius of curvature of the inner wall is at least 20%, in particular at least 40% of the specified height of the inlet channel.

For a preferred and economical manufacture of a sprinkler device, in particular from injection molded parts, the inlet channel is limited in the deflection zone by the surfaces of the lower part and the cover fixed to it, while the first channel section between the switching device and the deflection zone is formed in the lower part. The first inner wall is preferably formed on the lower part, and the outer wall on the lid, whereby a preferred shape of injection molding tools for the lower part and the lid is also provided for bending the restriction of the supply channel in the deflection zone.

Another significant improvement is the result of a favorable passage for the flow and to prevent the formation of vortices of the last section of the channel ending at the inlet nozzles, called in the subsequent third section of the channel, the angular length of which is assumed to be at least 30 ° around the turbine axis. The implementation provides that lying on the turbine axis radially outside, bounding the feed channel, the outer wall, which is also called the third outer wall, passes without kinks with continuous bending. The radius of curvature of the third outer wall is preferably not less than 15%, in particular not less than 25% of the radius of the turbine, which means the outer radius of the ring-shaped system of turbine blades. The radius of curvature may vary during the passage of the third section of the channel.

The third section of the channel passes with a continuous narrowing in the direction of the inlet nozzle, which leads to an increase in the speed of the driving water flow in the direction of the inlet nozzle. Due to the passage without kinks with a continuous bending of the third section of the channel, due to the absence or slight swirl, a small flow resistance and a high output speed of the driving water flow from the inlet nozzle in the direction of the turbine blades are obtained, and preferably a large torque in the turbine.

The inner wall of the third channel section preferably also extends without kinks and without steps, in particular also with a monotonous bend.

For the turbine blades of the turbines of these sprinkler devices, design constraints are set, in particular, in order to enable rotation in two directions, the guide surfaces of the blades arranged in pairs with mirror symmetry relative to the corresponding radial lines, and that the turbines are usually made of injection-molded plastic parts. The reason mentioned last leads to the fact that the turbine blades are, as a rule, axially connected with respect to the turbine axis on one side with a support ring common to all blades, and have a substantially constant cross section along the length perpendicular to the plane of the support ring. Due to this, the shape of the guide surfaces can be described with a single line in the parallel plane of the support ring of the cut plane.

The execution of the guide surfaces in such a way that they end on a radially lying end edge inclined at an angle of incidence relative to the radial line results in the exit of the water flow from the intermediate space actually loaded by the inlet nozzle between the guide surfaces facing each other in the intermediate, surrounded by a ring of turbine blades the space to the outlet for the flow of water in the direction opposite to the corresponding direction of rotation of the turbine ialnoy flow component, which promotes the formation force for starting torque of the turbine. The guide surfaces are concave-curved from the intermediate space. The turbine blades preferably each have two opposing to each other and coordinated with one of both directions of rotation of the turbine guide surfaces and preferably have a smaller width on their ends lying radially inside than on the ends lying radially outside.

The gaps at the radially inside ends of the turbine blades between two facing surfaces of the guide vanes, through which the water exits from the intermediate space at the specified outlet angle, have a circumferential width that is preferably between 30% and 200%, preferably between 50% and 150% of the distance between successive gaps. The distance between successive gaps, as a rule, is equal to the maximum width of the turbine blades at the ends lying radially inside.

The following is a more detailed explanation of the invention based on preferred embodiments with reference to the accompanying drawings, in which:

FIG. 1 is a part shown partially in section of a sprinkler device;

FIG. 2 - turbine with supply channels, in a plan view;

FIG. 3 is an embodiment of a turbine according to FIG. 2;

FIG. 4 is a preferred embodiment of a turbine;

FIG. 5 is an enlarged view of a section in the area of the inlet nozzle.

In FIG. 1 is a partially cutaway perspective view of a transmission of a sprinkler device, the housing of which has a lower part UT and an upper part OT, which are made in the form of separate structural elements, in particular injection molded parts, and then assembled together in the manner shown. The housing is shown partially in section and at the same time opens up a view, in particular, of two supply channels. Only the dashed line shows the switching device UE, with the help of which one of the two supply channels is connected to the water inlet of the sprinkler device.

At the GA outlet, it is possible to attach the sprinkler head to the nozzle system, and such an attached sprinkler head is designed for two-way alternate rotation by means of a water-passing transmission of the sprinkler device around the rotary axis DA. The rotary axis DA passes vertically in sectorial sprinklers in a normal operating position, and horizontally in quadrangular sprinklers. The following description relates to a sector sprinkler with a vertical swivel axis, and position indications, such as above and below, relate to its normal operating position with a vertical swivel axis.

In FIG. 1 shows, as part of the lower part, the first two sections K11 of the first supply channel and K21 of the second supply channel, which extend through the deviation zones, a detailed description of which will be given below, into the second sections K12 of the first supply channel and K22 of the second supply channel. In the following, a description is made, unless explicitly stated otherwise, of only one of both supply channels. Both feed channels extend substantially mirror symmetrically with respect to the midplane containing the turbine axis.

The first portions K11, K21 of the channel pass between the switching device UE downstream in the direction of the deviation zones substantially vertically and parallel to the axis of the transmission turbine of the sprinkler device, while the axis of the turbine usually and in the shown embodiments runs parallel to the rotary axis DA.

Second channel portions K12, K22 extend as shown in FIG. 2, arcuate around a turbine TR, which is rotatably mounted about a turbine axis TA. The second sections of the channel go into the third sections K13, K23 of the channel, which end at the inlet nozzle AD and pass in front of it in the direction of flow along the angular zone W3 equal to at least 30 °. Preferably, the second and third sections of the channels pass into each other with continuous curvature without steps and kinks.

In the deviation zone between the first section K11 and the second section K12 of the first supply channel, the driving water flow deviates from the initially vertical main flow direction in the first channel section K11 to the horizontal direction when entering the second channel section, with respect to the turbine axis TA, the tangential main flow direction is approximately so that the change in the main direction of flow in the deflection zone is approximately 90 °. The arrow MS indicates the middle of the stream. Such a 90 ° deviation can be assigned an imaginary deviation axis, the direction of which is perpendicular to both the first and second main flow direction and which lies in the inner corner of both main flow directions, and with respect to which there is a radially external restriction of the supply channel and a radially internal restriction of the supply channel in the deviation zone. The restriction of the inlet channel lying radially outside relative to such an imaginary axis of deviation is defined by the first outer wall AU1, the inner restriction is determined by the first inner wall IU1.

The first outer wall AU1 is curved away from the inner space of the supply channel, while the radius of curvature during the passage of the outer wall AU1 in the flow direction can also change. The radius of curvature RA is shown for one location on the outer wall.

Similarly, the first inner wall IU1 is bent to the interior of the supply channel in the deflection zone. For the curvature of the first inner wall IU1, the radius RI of curvature is also shown for one location. The distance of the first inner wall IU1 from the first outer wall AU1 is indicated as the height UH of the inlet channel in the deflection zone.

The radii of RA and RI of curvature, as well as the height UH, can change during the passage of the deviation zone. The depth of the feed channel, measured as the size of the cross section in the direction of the imaginary axis of deviation UA, preferably remains substantially unchanged when deviating from the end of the first section K11 to the beginning of the second section K12 of the channel. If the cross-section of the inlet channel deviates in the deviation from the rectangular shape, then the depth of the inlet channel, the height UH of the inlet channel and the radii of curvature RA of the first outer wall AU1 and the radii of curvature RI of the first inner wall IU1 are measured in the direction passing through the middle of the stream and essentially perpendicular to it directions.

The radius of curvature RA is preferably not less than 30%, in particular not less than 60% of the maximum height UH of the inlet channel in the deflection zone. The radius of curvature RI of the first inner wall IU1 is preferably not less than 20%, in particular not less than 40% of the height UH.

Due to the curvature of the surface of the first outer wall AU1 and the first inner wall IU1 with the smallest values of the radius of curvature, a flow deviation is preferably provided in which the flow is prevented from swirling at typical flow velocities of the drive water stream or is at least significantly reduced in comparison with the known embodiments. Due to this, energy losses of the drive water flow at this location are preferably prevented and a higher drive power of the drive water flow in the turbine is achieved, which leads to higher starting torque and improved starting characteristics of the turbine.

In order to realize these preferred deflection zones, the surface of the first inner wall IU1 of the inlet channel is preferably formed on the lower part UT, and the first outer wall AU1 is formed on the upper part OT. This ensures a preferred embodiment of the injection molding tool, since injection molding tools can be performed for both the lower part and the upper part so that the corresponding halves of the tool can be moved relative to each other in the direction of the rotary axis and no additional increasing the cost of the tool and injection molding components of the tool, such as gates or the like. The upper part OT forms in the shown embodiment an upwardly shaped cup, which with its outer wall extends outside the lower part in the form of a lid, on the surface DE of which in the direction of the lower part the first outer wall AU1 is formed as a continuation of VD. In the shown preferred embodiment, the outer surface wall AU1 forming the extension VD of the lid surface DE fits snugly against the vertical wall of the inlet channel formed in the lower part in the continuation of the first channel section K11. Other transitions with complementary steps in the transition from the lower to the upper part in the area of the first outer wall AU1 in the deviation zone are also possible. Small deviations from such uniform continuous curvature in such transitions for the indicated radii of curvature are not taken into account.

As shown in FIG. 2, in a preferred embodiment, the inlet channel narrows continuously in the second channel section K12 without kink and steps and goes continuously into the third channel section K13, which leads up to the inlet nozzle AD. The second section K12 of the channel can also be made with a constant cross-section. The third section K13 of the channel is continuously narrowing in its passage to the inlet nozzle AD, thereby increasing the flow rate of the drive water flow in the direction of the inlet nozzle AD. The third channel portion K13 preferably has a continuously curved outer wall A3 and / or a continuously curved inner wall I3. The outer wall A3 or the inner wall I3 may also have a direct passage to the inlet nozzle AD. The radius of curvature of the outer wall A3 is preferably not less than 20%, in particular not less than 40% of the radius RT of the turbine TR. The radius of curvature of the inner wall I3 is preferably not less than 15%, in particular not less than 25% of the radius RT of the turbine TR. Referred to in the subsequent ramp angle (EW in FIG. 5), the angle between the main flow direction ES of the water leaving the inlet nozzle AD and the tangential direction to the turbine at the inlet nozzle is preferably not more than 45 °.

For the purpose of explaining the invention, the second and third portions of the channel that are not explicitly separated during the continuous transition are demarcated from each other so that the third channel section extends along the angular segment W3 at least 30 ° around the turbine axis TA in front of the inlet nozzle AD.

The third channel section so defined is also shown in FIG. 3 in an embodiment with a complex supply channel structure. With such a complex structure of the channel, the second channel section K12 continues not only in the third channel section K13, but also in the auxiliary auxiliary channel KH, which leads to the additional inlet nozzle directed to the turbine, which is offset in the circumferential direction relative to the inlet nozzle AD.

The drive water flow passes from the inlet nozzle AD to the turbine blades of the turbine TR and exerts a force, respectively torque. In a preferred embodiment, the drive water flow is directed into the inner space IR, surrounded by ring-shaped turbine blades. In a preferred embodiment, a bypass water flow is also directed through the inner space IR, which is quantitatively larger in most cases than the drive water flow, while the spring-loaded bypass valve is located in the bypass flow in front of the inner space IR, so that the previously separated flow paths are reconnected in the internal space IR and are directed further in the direction of the connection point GA, respectively, in the direction of the outlet for water connected to it a marketing system.

In order to divert the drive water flow radially outwardly directed to the turbine blades into the inner space IR, the interscapular spaces between successive turbine blades into which the drive water flows through the gaps between successive turbine blades at their radially lying ends extend to the inner space.

In FIG. 4 shows a preferred embodiment of a turbine TR with a plurality of turbine blades TS, which are uniformly arranged annularly around the turbine axis TA and are made in the form of axial protrusions from a common support ring SR. The turbine blades in this preferred embodiment have the form of guide surfaces, which are shown in FIG. 5 in the manner explained below, it is preferable to increase the torque acting on the turbine, in particular for starting the turbine. The turbine blades TS are made mirror-symmetric with respect to the mirror plane passing through the turbine axis TA, due to which, due to the regular arrangement of the turbine blades, such mirror symmetry is also ensured for the intermediate spaces ZR between successive turbine blades relative to the mirror mirrors passing through the intermediate spaces and containing the turbine axis planes. Such mirror symmetry is common in the bi-directional turbines of sprinkler gear transmissions.

Below is a more detailed explanation of the features of the preferred embodiment of the turbine blades, with reference to FIG. 5, in which an enlarged view shows the turbine of FIG. 4 views in the housing according to FIG. 2 or 3.

The driving water stream exiting the inlet nozzle AD has the main flow direction ES at the outlet of the inlet nozzle AD, which extends at an entry angle EW relative to the tangential direction of the turbine sweeping circle, and this inlet angle is not greater than 45 °. Due to the water flowing from the inlet nozzle AD into the intermediate space between two adjacent turbine blades of water, water is simultaneously displaced from this intermediate space ZR, which flows out through the lumen LU between the end edges lying radially inside the relative to the turbine axis TA and limiting guide surfaces opposite to the intermediate space ZR, in internal space IR. The guide surface loaded by the flow of water from the inlet nozzle AD may preferably be concave-curved away from the intermediate space ZR. The guide surface loaded by the driving water flow from the inlet nozzle extends at its end lying inside the relative to the turbine axis TA, with an inclination of the angle AW of the incidence relative to the radial line into the inner space. Therefore, the water displaced from the intermediate space ZR has, when exiting the intermediate space ZR through the gap LU between adjacent turbine blades, a flow direction AS that is directed against the radial direction opposite to the turbine rotation direction DR corresponding to the inlet nozzle AD. Due to this, in particular in the situation of starting the turbine, additional force acts on the turbine and the starting torque is increased. The outlet angle AT is preferably at least 15 °, in particular at least 25 °. The output angle is preferably not more than 50 °. When viewed in the DR direction of rotation of the turbine, the width LL of the gaps LU is preferably between 30% and 200%, preferably between 50% and 120% of the distance LS between adjacent gaps.

The above and in the claims, as well as in the figures, the features can preferably be implemented both individually and in various combinations. The invention is not limited to the exemplary embodiments explained above, and may be modified in various ways within the knowledge of those skilled in the art.

Claims (16)

1. A sprinkler device comprising a water inlet and forming a water outlet a sprinkler head mounted to rotate relative to the main body, wherein the sprinkler head is rotated by transmitting a sprinkler device that is driven by a turbine with a plurality of turbine blades rotating around a turbine axis, wherein
- a drive water stream passes through the turbine, which forms at least a portion of the total water stream passing from the water inlet to the water outlet,
- the turbine is made to rotate in two opposite directions of rotation,
- for each direction of rotation, one of two supply channels is provided, each of which is equipped with at least one inlet nozzle that determines the direction of run,
- using the switching device located downstream of both supply channels, it is possible to optionally connect one of both supply channels to the water inlet,
- and at the same time the path of the water flow is made optimally in hydrodynamics and with small turbulences for the passage of the flow so that
a) the inlet channel has a deviation of direction between the first section of the inlet channel, at least predominantly parallel to the turbine axis, and the second section of the channel extending essentially in the plane of the turbine blades radially outside the turbine blades, and in the area of this deviation of direction is limited by the first outer wall and the first inner wall, and the outer wall is free from kinks, continuously curved passage, and / or
b) a third section of the channel ending at the inlet nozzle, passing along an arc at least partially around the turbine and at the same time monotonously tapering, is bounded radially from the outside by the third outer wall, which has in the circumferential direction free of breaks continuously curved passage in the form of an arc, and / or
c) the flow path runs from the inlet nozzle lying radially outside the turbine blades, forming a ring around the inner space, and inclined at an angle of incidence of less than 45 ° relative to the tangent to the turbine, through the gaps located at the radially inner ends of the turbine blades between adjacent turbine blades, radially into the inner space, and the guide surfaces of the turbine blades loaded by the flow from the inlet nozzle pass concave-curved and at an incidence angle inclined relative to itelno radial line, and in the opposite direction corresponding to the rotation direction, are located on the internal space. 2. Sprinkling device according to claim 1, characterized in that the radius of curvature of the first outer wall is at least 30%, in particular at least 60% of the height of the inlet channel in the deflection zone. 3. The sprinkler device according to claim 1, characterized in that the inwardly limiting supply channel in the deflection zone, the first inner wall passes without kinks with continuous bending. 4. The sprinkler device according to claim 2, characterized in that the first internal wall bounding the inside of the supply channel in the deflection zone passes without kinks with continuous bending. 5. Sprinkling device according to claim 3, characterized in that the radius of curvature of the first inner wall is at least 20%, in particular at least 40% of the height of the inlet channel. 6. Sprinkling device according to claim 4, characterized in that the radius of curvature of the first inner wall is at least 20%, in particular at least 40% of the height of the inlet channel. 7. Sprinkling device according to claim 1, characterized in that the second section of the channel is limited by the surfaces of the lower part and the lid attached to it. 8. The sprinkler device according to claim 7, characterized in that the surface of the first outer wall is formed on the lid. 9. Sprinkling device according to any one of claims 1 to 6, characterized in that the deviation of the direction between the first and second section of the channel is 90 °. 10. Sprinkling device according to claim 1, characterized in that the curvature of the third outer wall is at least 20%, in particular at least 40% of the radius of the turbine. 11. The sprinkler device according to claim 1, characterized in that the direction of the driving water flow at the outlet of the inlet nozzle passes with an inclination of less than 45 ° relative to the tangent to the direction of rotation of the turbine. 12. Sprinkler device according to claim 1, characterized in that the output angle is at least 15 °, in particular at least 25 °. 13. Sprinkling device according to item 12, wherein the output angle is a maximum of 50 °. 14. The sprinkler device according to claim 1, characterized in that the length of the lumens in the circumferential direction is between 30% and 200% of the distance between successive lumens. 15. The sprinkler device according to claim 1, characterized in that the turbine is rotatably mounted by means of a turbine shaft, and the turbine shaft is surrounded by an elastic seal. 16. The sprinkler device according to claim 15, characterized in that the diameter of the turbine shaft is not more than 1.5 mm.

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