CZ2009616A3 - Controllable nozzle - Google Patents

Abstract

A controllable nozzle for supplying liquid or gaseous medium with a long range, the principle of which is that an inner nozzle (2) is placed inside the main nozzle (1) coupled with a guide means (6) for reciprocating movement of the inner nozzle (2) in the direction of the longitudinal axis ( 5) internal nozzle (2). The inlet (12) of the main nozzle (1) and the inlet (22) of the inner nozzle (2) are connected to the main supply space (3) of the liquid or gaseous medium, the outlet (11) of the main nozzle (1) and the outlet opening ( 21) the internal nozzles (2) result in a common outlet (4). The taper of the main nozzle (1) is greater than that of the inner nozzle (2). The guide means (6) of the inner nozzle (2) is formed by a guide rod (17) fixedly connected to the inner nozzle (2) via a fastening element (10). The guide bar (17) is slidably guided by the holder (9).

Description

Technical field

The invention relates to a controllable nozzle for supplying a liquid or gaseous medium, allowing the amount of liquid or gaseous medium to be discharged or dispensed. Its construction allows a long range of the outgoing gaseous or liquid medium.

BACKGROUND OF THE INVENTION

A disadvantage of conventional nozzles, for example for the supply of air to interior spaces, is the impossibility of effectively changing their flow cross section and thus controlling the amount of air flowing through the nozzle. The most common way to control the amount of air is by throttling, with a throttle reducing the pressure upstream of the nozzle. Such a solution is described in US-A-3919929, Int. Cl. F 24 F 13/08 relating to a control device for multiple air distribution.

An analog of said control device is that disclosed in U.S. Pat. No. 4,006,663, Int. Cl. ² F 24 F 13/06 concerning adjustable air nozzle for car heating and ventilation systems. Here the throttle is located directly in the probe body. However, the throttle is an excess element of the system and its greatest disadvantage is obstructing the pressure energy of the air flow, which results in a lower velocity of the air exiting the nozzle and thus a lower air flow.

Another known solution consists in providing a body which closes the central part of the flow cross section of the nozzle and the axial displacement of the body changes the flow cross section of the nozzle. Such a solution is disclosed, for example, in U.S. Pat. No. 4191098, Int. Cl. ² F 24 F 13/06, which relates to the construction of a nozzle for air conditioners, and also to U.S. Patent Application Publication No. 2008/0112155, Int. Cl. F 21 V 33/00, published May 15, 2008 concerning integrated light and passenger air outlet for passengers in vehicles. The disadvantage of this solution can be seen in the fact that the flow cross-section of the nozzle is not circular but slotted and the air flow exiting the nozzle has a smaller range compared to the circular cross-section of the nozzle with the same mass flow.

Nozzle solutions with variable flow cross-section are also known. Most often it is the use of slotted nozzles, in which the flow cross section of the nozzle is formed by a slot, which can be clamped and thus change the flow cross section.

US

The contents of U.S. Pat. No. 5,226,601, Int. Cl. B 05 B 7/08 is a double hydrotherapy nozzle with extended aeration. According to this solution, an outer and an inner conical nozzle is used, wherein the inner nozzle is displaceable axially within the outer nozzle. The conicity of the outer and inner nozzles is identical so that the walls of the two nozzles are parallel to each other. Holes are formed around the periphery of the outer nozzle wall, which partially overlap the inner nozzle wall. Pressurized water is supplied to the inner space of the inner nozzle,

whereas air is sucked in through the holes in the outer nozzle wall, the amount of which can be controlled by the axial displacement of the inner nozzle. The inlet of the pressurized water into the nozzle system is only made possible by the internal nozzle, behind which the mixing chamber is located. A cylindrical outlet of aerated water is attached to the outlet of the outer nozzle.

It is an object of the present invention to provide a controllable nozzle with a long-range liquid or liquid jet. a gaseous medium whose construction provides laminar flow throughout the nozzle adjustment range.

SUMMARY OF THE INVENTION

According to the invention, the object is achieved by the construction of a controllable nozzle, characterized in that at least one inner nozzle coupled to the guide means for reciprocating the inner nozzle within the main nozzle in the direction of the longitudinal axis of the inner nozzle is arranged inside the main nozzle body. the nozzles and the inlet nozzle of the inner nozzle are connected to the main supply chamber of the liquid or gaseous medium. At the outlet of the two nozzles, the outlet of the main nozzle and the outlet of the inner nozzle are led to the common outlet space. Both the main nozzle and the internal nozzle have a conical profile or a profile of a quadrilateral or multilateral pyramid. Then, the inlet opening of the main nozzle is larger than its outlet opening, the main nozzle being formed by a tapering wall in the direction of its outlet opening. Also, the inlet orifice of the inner nozzle is larger than its outlet orifice and the nozzle is formed by a tapering wall in the direction of its outlet orifice.

According to a further feature of the invention, the conicity of the main nozzle is greater than that of the internal nozzle.

According to another feature of the invention, the inlet opening of the main nozzle as well as the inlet opening of the inner nozzle is a cylindrical profile or a square or polygonal profile.

It is also within the scope of the protection that the guide means of the inner nozzle is formed by a guide rod which is fixedly connected to the inner nozzle by a fastening element. The inner nozzle guide rod is coupled to the movement mechanism to move the inner nozzle in the direction of its longitudinal axis. Alternatively, the inner nozzle guide means is formed by a holder firmly connected to the inner side of the main nozzle inlet wall and / or firmly connected to the inner side of the tapered main nozzle wall. The bracket then surrounds the outer periphery of the inlet nozzle of the inner nozzle with its central portion. Either a threaded connection or a sliding joint is formed between the central part of the holder and the outside of the wall of the inlet nozzle of the inner nozzle to allow the inner nozzle to move in the direction of its longitudinal axis. To this end, for example, the inner nozzle is again firmly connected to the guide rod by means of a fastening element, and the guide rod is further coupled to a movement mechanism to provide controlled movement of the inner nozzle in the longitudinal axis thereof, either by rotating the guide rod or by sliding the guide rod.

By the axial movement of the inner nozzle located inside the main nozzle, the inter-circular cross section formed by the outlet diameter of the main nozzle and the outer wall of the inner nozzle is changed. The axis of symmetry of the inner nozzle is identical to the axis of symmetry of the main nozzle.

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Advantageously, the largest diameter of the inner nozzle is larger than the outlet opening of the main nozzle. In this case, the flow cross-section between the two nozzles can be completely closed and only the flow cross-section equal to the outlet opening of the inner nozzle is retained for the outlet. The total flow cross-section of both nozzles can be precisely adjusted by the axial displacement of the inner nozzle. axially symmetrical, whereby the output stream of the liquid or gaseous medium has a long range.

BRIEF DESCRIPTION OF THE DRAWINGS

The controllable nozzle solution according to the invention is shown schematically and in the exemplary embodiments in the drawings, in which Fig. 1 shows the arrangement of the main nozzle and the inner nozzle including the guiding means for moving the inner nozzle along the longitudinal axis of the nozzle assembly. FIG. 1 with a holder to allow movement of the inner nozzle in the direction of the longitudinal axis of the nozzle assembly; and FIG. 3 is a perspective view of the assembled nozzle of FIG. 2 from the main inlet side.

DETAILED DESCRIPTION OF THE INVENTION

The adjustable long-range nozzle of FIG. 1 comprises a main nozzle X and an inner nozzle 2. The main nozzle 1 comprises its inlet opening 12 having a cylindrical wall portion 15 with a wall

7. The cylindrical part 15 of the main nozzle X is connected to its tapering wall 13 terminated by the outlet opening XX. The cylindrical part 15 of the main nozzle X is connected to the main supply chamber 3 of liquid or gaseous medium. The inlet orifice 22 of the inner nozzle 2 is followed by a tapering wall 23 thereof, terminated by an outlet orifice 21 of the inner nozzle 2. The main nozzle X is housed in the housing 8. The conicity of the main nozzle X is greater than that of the internal nozzle 2.

The inner nozzle 2 is provided at the inlet opening 22 with a fastening element 10 with which the guide means 6, here implemented by means of a guide rod 17, is slidably guided in a holder 9 attached to the inner side of the wall 7 of the cylindrical portion 15 of the main nozzle 15. Alternatively, the guide rod 17 in the holder 9 can be replaced by a threaded connection. The guide rod 17 is then connected to a movement mechanism (not shown) to provide controlled movement of the inner nozzle 2 in the direction of its longitudinal axis 5.

The liquid or gaseous medium enters the main nozzle X and at the same time into the inner nozzle 2 from the main supply chamber 3 through the inlet opening 12 of the main nozzle X and through the inlet opening 22 of the inner nozzle 2. and at the same time it exits the inner nozzle 2 through the outlet opening 21 into the common outlet space 4. By moving the inner nozzle 2 with respect to the main nozzle X in the direction of the longitudinal axis 5, the cross-section of the outlet opening 11 of the main nozzle χ is changed. When a smaller nozzle flow is required, the inner nozzle 2 moves toward the main nozzle outlet opening 11 and the nozzle flow decreases. As a limit, the outlet opening 11 of the main nozzle 4 can be completely closed and the gaseous fluid exits the nozzle into the common outlet space 4 only through the outlet opening 21 of the inner nozzle 2.

The controllable nozzle of FIG. 2 differs from the embodiment shown in FIG. 1 in the construction of the attachment of the inner nozzle 2 to the main nozzle 1. To the inner surface of the wall 7 of the cylindrical portion 15 and partially to the tapered wall 13 of the main nozzle X the central portion 14 forms a guide for the cylindrical portion 16 of the inner nozzle 2. Between the cylindrical portion 16 of the inner nozzle 2 and the central portion 14 of the holder 9, either a sliding guide is formed or a threaded connection is formed. The regulated movement of the inner nozzle 2 in the direction of its longitudinal axis 5 is effected either by rotating the inner nozzle 2 or by sliding the inner nozzle 2. For this purpose, the inner nozzle 2 can again be firmly connected to the guide rod 17 (Fig. 1) by fastening element 10 located in the inlet opening 22 of the inner nozzle 2 and the guide rod 17 are further coupled with a movement mechanism (not shown) to provide controlled movement of the inner nozzle 2 in the direction of its longitudinal axis 5. The controlled axial movement of the inner nozzle 2 is realized either by rotating the guide rod 17 or by sliding the guide bars 17.

FIG. 3 is a perspective view of the controllable nozzle corresponding to the controllable nozzle structure of FIG. 2. The inlet opening 12 of the main nozzle 1 bounded by the wall 7 is connected to the main supply chamber 3 effected by an exemplary liquid or gaseous manifold. The inner nozzle 2 is supported and axially guided by a central part 14 surrounding the inlet opening 22 of the internal nozzle 2. Between the inner surface of the wall 7 of the main nozzle X and the central part 14 is a holder 9, in this case triple plates. by the inner surface of the wall 7 of the main nozzle 1 and on the other hand firmly connected to the central part 14 surrounding the inlet opening 22 of the inner nozzle 2.

The controllable nozzle according to the invention can be used, for example, in the field of air conditioning, as an end element of garden water hoses, water purification hoses or as a nozzle of fire hoses. The nozzle design provides output laminar flow over the entire nozzle adjustment range, ensuring far reach of the jet.

In the field of ventilation, the adjustable nozzle can be used as a distribution terminal element for supplying air to ventilated rooms. Similarly, the nozzle can be used in technical applications using air to cool, heat and uniformize temperatures, such as in hot air furnaces, blow molds, glass manufacturing, and the like.

Another typical example of the use of a controllable nozzle is when air is supplied to the intake manifold from which individual nozzles arranged along the intake manifold are supplied. By using the adjustable nozzles according to the invention, the entire assembly can be regulated so that the desired air flow flows through each nozzle.

Claims (10)

PATENT CLAIMS A controllable nozzle for supplying a liquid or gaseous medium with a long range, characterized in that at least one inner nozzle (2) coupled to the guide means (6) for reciprocating the inner nozzle (2) is arranged inside the main nozzle (1). a main nozzle (1) in the direction of the longitudinal axis (5) of the inner nozzle (2), the supply nozzle (12) of the main nozzle (1) and the inlet opening (22) of the inner nozzle (2) communicating with the main supply chamber (3) or gaseous medium, while the outlet (11) of the main nozzle (1) and the outlet (21) of the inner nozzle (2) open into a common outlet space (4). Adjustable nozzle according to claim 1, characterized in that the inlet opening (12) of the main nozzle (1) and the inlet opening (22) of the inner nozzle (2) have a cylindrical profile or a profile of a square or a polygon. Adjustable nozzle according to claim 1, characterized in that the inlet opening (12) of the main nozzle (1) is larger than its outlet opening (11) and the main nozzle (1) is formed by a tapering wall (13) towards the outlet opening (11) of the main nozzle (1). Adjustable nozzle according to claim 1, characterized in that the inlet opening (22) of the inner nozzle (2) is larger than its outlet opening (21) and the inner nozzle (2) is formed by a tapering wall (23) towards the outlet bore (21) of the inner nozzle (2). Adjustable nozzle according to claim 1, characterized in that the main nozzle (1) has a conical profile or a profile of a quadrilateral or multilateral pyramid. Adjustable nozzle according to claims 1 and 4, characterized in that the inner nozzle (2) has a conical profile or a profile of a quadrilateral or multilateral pyramid. Adjustable nozzle according to claim 5 and 6, characterized in that the conicity of the main nozzle (1) is greater than that of the inner nozzle (2), Adjustable nozzle according to claim 1, characterized in that the guide means (6) of the inner nozzle (2) is formed by a guide rod (17) firmly connected to the inner nozzle (2) by means of a fastening element (10). Adjustable nozzle according to claim 1, characterized in that the guide means (6) of the inner nozzle (2) is formed by a holder (9) firmly connected to the inside of the wall (7) of the inlet opening (12) of the main nozzle (1). or with the inner side of the tapered wall (13) of the main nozzle (1), wherein the holder (9) surrounds the outer periphery of the inlet nozzle (22) of the inner nozzle (2) with its central portion (14). Adjustable nozzle according to claim 9, characterized in that a threaded connection or sliding connection is provided between the central part (14) of the holder (9) and the outside of the wall of the inlet opening (22) of the inner nozzle (2).