DE102013109387A1 - Nozzle and system with such - Google Patents

Abstract

The invention relates to a nozzle (100, 300, 400) for connection to a fluid line (200), comprising an outer wall (105) and an inner bore (104) surrounded by the outer wall (105), which can be connected to the fluid line (200 ), wherein the outer wall (105) has a plurality of recesses (106), wherein the recesses (106) in the outer wall (105) have different dimensions.

Description

The present invention relates to a nozzle according to the preamble of claim 1 and to a system having such a nozzle.

Nozzles for connection to a fluid line are known from the prior art. From the US 5,253,716 is known a nozzle for fire fighting, having an inner bore with two different diameters. The inner bore is surrounded by an outer wall. The outer wall has the same size slots through which a fluid can be sprayed. The slots are aligned so that the emerging from a slot fluid jet collides with the exiting from another slot fluid jet. Thus, a mist is to be generated, which should be particularly advantageous in the fight against fire.

In this case, due to the flow conditions in the nozzle, a large proportion of the fluid initially flows up to the end opposite the connection for the fluid line, which is closed by the outer wall. The pressure of the fluid is relatively high, so that more fluid exits through the recesses at this end of the nozzle than through the recesses, which are arranged closer to the connection for the fluid line.

In addition, rotating nozzles are known in the art. However, they have the disadvantage that the amount of the sprayed fluid is very large.

From US 5,253,716 known nozzle and other known from the prior art nozzles thus have the disadvantage that different amounts of fluid emerge from the nozzle openings. For a fire fighting a uniform spraying is of secondary importance. In the area of spraying surfaces with a surface treatment agent, the uniformity is of high importance. For example, when the surface of a cavity is to be sprayed with the surface treatment agent through a comparatively small opening, it is of particular importance that the surface treatment agent be sprayed as uniformly as possible. This is especially true when the opening is so small that only the nozzle and possibly even a part of the fluid line can be inserted into the cavity. With such a small opening, the possibility of movement of the nozzle is extremely limited. Particularly uniform spraying avoids spraying more or less certain areas and prevents wastage of the surface treatment agent. The most uniform possible spraying may be desired, for example, in the disinfection of surfaces or in the killing and removal of mold fungi.

Therefore, it is an object of the present invention to provide a nozzle with which a fluid can be uniformly sprayed in multiple directions, and a system with such a nozzle.

This object is achieved by a nozzle having the features of claim 1 and by a system according to claim 12. Embodiments of the invention are indicated in the dependent claims.

According to claim 1, the recesses in the outer wall of the nozzle to different extents. This feature ensures that a fluid flowing through the inner bore exits particularly uniformly from all the recesses. The fluid may be, for example, a disinfectant. For example, the recesses closer to the fluid line port may be larger while the recesses at the other end of the nozzle may be smaller. In this case, the nozzle may be formed, for example, as a blind hole. In this case, the end of the nozzle opposite the connection for the fluid line is closed by the outer wall.

The proportion of the fluid flowing through the recesses closer to the fluid line port than the other end of the nozzle can be increased by making the dimensions of these recesses larger than the recesses closer to the closed end of the nozzle are. By a larger recess of the flow resistance is reduced and more fluid flows through the recess. It is also possible for the recesses, which are closer to the end of the nozzle closed by the outer wall, to be smaller, so that here the flow resistance increases and less fluid flows through the recesses. This ensures that the fluid flows out of the recesses particularly evenly.

The nozzle according to the invention is particularly advantageous for uniformly spraying the disinfectant forwards, backwards and laterally.

According to one embodiment of the invention, the nozzle may have a first end portion and a second end portion opposite to each other. Between the two end portions of the inner bore extends. The first end region may be formed, for example, for connection to the fluid line, while the second end region may be formed as a blind hole. The dimensions of the Recesses can become smaller from the first end region to the second end region.

According to one embodiment of the invention, the inner bore may have different dimensions. This is also advantageous for a particularly uniform spraying of the fluid. For example, the cross-sectional area of the inner bore may decrease from the first end portion toward the second end portion. For example, the inner bore may have different sized circular cross-sectional areas. In such a case, the diameter of these cross-sectional areas may decrease from the first end portion toward the second end portion.

According to one embodiment of the invention, the diameter may change stepwise. Thus, for example, there may be a first region of the inner bore, in which the inner bore has a constant first diameter. This may be followed by a second region of the inner bore, in which the inner bore has a constant second diameter, which is smaller than the first diameter. Other areas with even smaller diameters may also be provided. This is particularly advantageous for a uniform spraying of the fluid. In addition, such an internal bore is particularly easy to manufacture.

According to one embodiment of the invention, the inner bore may have a different diameter at each of the recesses. In other words, the diameter of the inner bore can each change between two of the recesses. It is also possible that the diameter of the inner bore always changes between two recesses. As a result, the diameter of the inner bore can be particularly well adapted to the dimensions of the respective recess, whereby a particularly uniform spraying of the fluid is achieved.

According to one embodiment of the invention, the recesses may be slit-like. The term "slit-like" is understood here in particular that the dimensions of the recesses in a direction transverse to the flow direction of the fluid in the inner bore are many times greater than the dimensions of the recesses in a direction parallel to the flow direction of the fluid in the inner bore.

According to one embodiment of the invention, the recesses may each extend over more than half the circumference of the outer wall. Preferably, a slot-like recess in a direction along the outer wall may be at least as large as half the circumference of the outer wall plus a half circumference of the inner bore.

It is also possible that the edges of the recesses are rounded. This improves the outflow behavior of the fluid. There is less turbulence, the trailing edge of the flow of the fluid is softer and the fluid can flow out more evenly.

Furthermore, it is possible that the nozzle has fastening means. The attachment means may be used to attach a weight to the nozzle. The nozzle may then sink by gravity within a cavity to near the bottom, even though the hole through which the cavity is reached is relatively far from the ground. Thus, the surfaces of the cavity can be sprayed very easily and evenly. This is particularly advantageous if the fluid line attached to the nozzle is deformable, that is, for example, designed as a hose.

Another possibility is that the recesses are formed such that a jet of the fluid exiting a recess encloses a different angle with the flow direction of the fluid within the inner bore than another jet exiting from another recess. This can apply to all recesses. It may therefore be that the recesses are formed so that the fluid jets emerging through the recesses all include different angles with the flow direction of the fluid in the inner bore.

According to one embodiment of the invention, the recesses may each have two ends and a central region. In each case, the ends may be arranged closer to the first end region of the nozzle or closer to the second end region of the nozzle than the central region of the recess. The recesses can therefore also be referred to as notches, which enclose an angle of not equal to 90 ° with the inner bore.

According to one embodiment of the invention, in the recesses which are closer to the first end region than the second end region of the nozzle, the ends of the respective recess may be closer to the second end region of the nozzle than the central region of the respective recess. In the recesses which are closer to the second end region than the first end region of the nozzle, the ends of the respective recess may be closer to the first end region of the nozzle than the central region of the respective recess.

According to one embodiment of the invention, the recesses may be divided into two groups be arranged. The spacing of the groups from each other can be many times greater than the spacing of the recesses within a group. Preferably, the distance of the groups from each other is at least four times, in particular four to six times, the distance between two recesses of a group.

It is also possible that the recesses comprise exactly two groups. In this case, a first group may be closer to the first end region than to the second end region. A second group may be closer to the second end region than the first end region. Each of these groups can comprise exactly two recesses. Now, if the distance of the groups from each other is greater than the distance of the recesses of a group from each other, a particularly uniform distribution of the fluid is achieved. If the distances of the groups from one another are too small, it is possible that more fluid flows out of the recesses, which are arranged farther away from the fluid connection than out of the remaining recesses.

According to claim 12, a system comprises a nozzle according to an embodiment of the invention and a fluid conduit connected to the nozzle via a port of the nozzle.

Further features and advantages of the present invention will become apparent from the following description of preferred embodiments with reference to the accompanying drawings. Here, the same reference numerals are used for the same or similar components and components with the same or similar functions. It shows

1 a schematic representation of a nozzle according to an embodiment of an invention;

2 a schematic representation of a system comprising a nozzle disposed in a cavity;

3 a schematic representation of a nozzle with fastening means for a weight; and

4 a schematic representation of a nozzle with a further recess.

The nozzle 100 has a connection 102 for a fluid line. This may be, for example, a fluid line connecting the nozzle to a container for a disinfectant to kill molds. At the connection 102 For example, a thread can be arranged, with which the fluid line to the nozzle 100 can be attached.

In addition, the nozzle points 100 an inner bore 104 , one the inner bore 104 surrounding outer wall 105 and several in the outer wall 105 arranged recesses 106 ' - 106 '''' on. The inner bore has several areas 108 ' - 108 '''' on. The area 108 is the connection 102 closest and has in comparison with the other areas 108 '' - 108 '''' the largest cross-sectional area. The area 108 '''' is furthest from the connection 102 and shows in comparison with the other areas 108 ' - 108 '''' the smallest cross-sectional area. The cross-sectional area of all areas 108 ' - 108 '''' is circular. Thus, the areas differ 108 ' - 108 '''' the inner bore 104 through their different diameters. In this case, the area indicates 108 ' the largest diameter, the area 108 '' the second largest diameter, the area 108 ''' the third largest diameter and the area 108 '''' the fourth largest, or even the smallest, diameter. The area 108 '' is between the areas 108 ' and 108 ''' arranged. The area 108 ''' is between the areas 108 '' and 108 '''' arranged.

In each of the areas 108 ' - 108 '''' is a recess 106 ' - 106 '''' arranged. The dimensions of the recesses 106 ' - 106 '''' are different from each other. This is especially true for the width of the recesses 106 ' - 106 '''' to. Below the width of the recess 106 ' - 106 '''' is understood here in particular the direction perpendicular to the outflow direction of the fluid through the respective recess 106 ' - 106 '''' runs. The in the area 108 ' arranged recess 106 ' has the largest proportions. The in the area 108 '' arranged recess 106 '' has the second largest size. The in the area 108 ''' arranged recess 106 ''' has the third largest size. The in the area 108 '''' arranged recess 106 '''' has the smallest dimensions.

Furthermore, it is off 1 you can see that the recesses 106 ' - 106 '''' include an angle of less than or greater than 90 ° with the internal bore. This arrangement contributes to the uniform distribution of a fluid to be sprayed.

The recesses 106 ' and 106 '' are formed such that one of these recesses 106 ' and 106 '' outflowing fluid flows in a direction having a first directional component, which in the direction of the terminal 102 has. The recesses 106 ''' and 106 '''' are formed such that one of these recesses 106 ''' and 106 '''' outflowing fluid flows in a direction having a first directional component away from the port 102 has.

In addition, the recesses 106 ' - 106 '''' designed to be the direction of the outflowing fluid has a second directional component. The second directional component is perpendicular to the longitudinal axis of the inner bore 104 directed. At the recess 106 ' and 106 '''' this second directional component is opposite to the second directional component at the recesses 106 '' and 106 '''' directed. By this arrangement of the recesses 106 ' - 106 '''' a particularly uniform spraying is possible.

The nozzle 100 is particularly advantageous to perform disinfections in poorly accessible cavities. By the arrangement of the recesses 106 ' - 106 '''' , the configuration of the recesses 106 ' - 106 '''' and the changes in the diameter of the inner bore 104 in the fields of 108 ' - 108 '''' a particularly uniform spraying of the fluid is achieved. A user does not have to pay attention to an even distribution, since this happens automatically. For example, the nozzle may be inserted into the cavity through a hole in a wall of the cavity. Due to the design of the nozzle 100 the cavity is evenly sprayed with the fluid. In this case, a rotational movement or rotation of the nozzle is not required. Even an inexperienced user can perform such a disinfection.

The nozzle can be easily moved by a user towards the nozzle to achieve a particularly uniform spraying of the surfaces of the cavity.

It is also in 1 shown that the recesses 106 ' and 106 '' form a first group, which is the first end region with the connection 102 closer than the second is the connection 102 opposite end region. The two recesses 106 ''' and 106 '''' form a second group that is closer to the second end region than the first end region. The distance of the groups from each other is slightly more than five times the distance between the recesses 106 ' and 106 '' and the distance between the recesses 106 ''' and 106 '''' , This further contributes to a uniform outflow of the fluid from the recesses 106 ' to 106 '''' at.

In 2 is the nozzle 100 shown attached to a fluid line 200 is arranged. The nozzle 100 is also in a cavity 201 arranged. Using the nozzle 100 should the cavity 201 as uniformly as possible with a surface treatment agent, such as a disinfectant to kill molds, sprayed. To the fluid line 200 are operating means 202 Connected via which a user the flow of a fluid through the fluid line 200 can control. Thus, the user can control whether the surface treatment agent passes through the fluid line 200 in the nozzle 100 should flow.

Once the fluid enters the nozzle 100 flows, it occurs due to the design of the nozzle 100 evenly from all recesses 106 ' - 106 '''' out. The surfaces of the cavity 201 are sprayed so evenly. A rotational movement of the nozzle 100 is not necessary for this. Thus, an inexperienced low-sensitivity user can also spray the surfaces of the cavity 201 make.

The nozzle 100 and a part of the fluid line 200 are through a recess 204 in a wall of the cavity 201 in the cavity 201 introduced. Due to the small size of the recess 204 is a movement of the nozzle in the 2 shown position up or down hardly or not possible. Such a small recess 204 is especially advantageous if a destruction of the walls of the cavity 201 should be kept as low as possible. For example, if the wall of the cavity with the recess 204 a wall or ceiling covering a building, it is advantageous to have the smallest possible recess 204 provided to minimize the damage.

The nozzle can be used, for example, for the disinfection of hollow, double or oscillating floors. These are used for example in sports halls. Further uses of the nozzle are the disinfection of tramps in the attic area, suspended ceilings, for example in offices, wall moldings, manholes of all kinds and climatic chambers and ventilation systems.

Due to the design of the nozzle 100 can the dimensions of the recess 204 in the direction perpendicular to the fluid line 200 be kept low.

In the 3 shown nozzle 300 indicates the connection 102 opposite end fastener 302 for a weight up. Using the fasteners 302 For example, a weight can be connected to the nozzle, so that the nozzle can be inserted into a cavity in which a passage opening is arranged on the top. This may be advantageous, for example, for the disinfection of cavities which are arranged below the floor. This can be the case, for example, in hollow or double floors or vibrating floors, for example in a gymnasium. Thus, even surfaces of such cavities in a simple manner evenly spray with a disinfection room.

In the 4 shown nozzle 400 indicates the connection 102 opposite end of a recess 402 on. The recess 402 may for example have a circular cross-sectional area. From the recess 402 can also do this through the inner bore 104 leaking fluid emerge. Thus, the fluid can also be sprayed in this direction, which further improves a uniform spraying of surfaces of a cavity.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• US 5253716 [0002, 0005]

Claims (13)

Jet ( 100 ; 300 ; 400 ) for connection to a fluid line ( 200 ), comprising an outer wall ( 105 ) and one of the outer wall ( 105 ) surrounded inner bore ( 104 ) for connection to the fluid line ( 200 ) is formed, wherein the outer wall ( 105 ) several recesses ( 106 ), characterized in that the recesses ( 106 ) in the outer wall ( 105 ) have different dimensions. Jet ( 100 ; 300 ; 400 ) according to claim 1, characterized in that the nozzle ( 100 ; 300 ; 400 ) has a first end portion and a second end portion, which are opposed to each other and between which the inner bore ( 104 ), the dimensions of the recesses ( 106 ) become smaller from the first end region to the second end region. Jet ( 100 ; 300 ; 400 ) according to claim 2, characterized in that the first end region for connection to the fluid line ( 200 ) is trained. Jet ( 100 ; 300 ; 400 ) according to at least one of the preceding claims, characterized in that the inner bore ( 104 ) has different dimensions. Jet ( 100 ; 300 ; 400 ) according to at least one of the preceding claims, characterized in that the inner bore ( 104 ) has different diameters, wherein the diameters decrease from the first end region in the direction of the second end region. Jet ( 100 ; 300 ; 400 ) according to at least one of the preceding claims, characterized in that the diameter of the inner bore ( 104 ) gradually changes. Jet ( 100 ; 300 ; 400 ) according to at least one of claims 4 to 6, characterized in that the inner bore ( 104 ) at each of the recesses ( 106 ) has a different diameter. Jet ( 100 ; 300 ; 400 ) according to at least one of the preceding claims, characterized in that the recesses ( 106 ) are formed slit-like. Jet ( 100 ; 300 ; 400 ) according to at least one of the preceding claims, characterized in that the recesses ( 106 ) each over more than half the circumference of the outer wall ( 105 ). Jet ( 100 ; 300 ; 400 ) according to at least one of the preceding claims, characterized in that the recesses ( 106 ) each have two ends and a central region, and that the ends of the first end portion or the second end portion of the nozzle ( 100 ; 300 ; 400 ) are closer than the mid-range. Jet ( 100 ; 300 ; 400 ) according to claim 10, characterized in that at the recesses ( 106 ) closer to the first end region than the second end region of the nozzle ( 100 ; 300 ; 400 ), the ends of the second end portion of the nozzle ( 100 ; 300 ; 400 ) are closer than the central region of the respective recess ( 106 ), and / or that in the recesses ( 106 ) closer to the second end region than the first end region of the nozzle (FIG. 100 ; 300 ; 400 ), the ends of the first end portion of the nozzle ( 100 ; 300 ; 400 ) are closer than the central region of the respective recess ( 106 ). Jet ( 100 ; 300 ; 400 ) according to at least one of the preceding claims, characterized in that the recesses ( 106 ) are arranged in two groups, wherein the distance of the groups from each other is many times greater than the distance of the recesses ( 106 ) within a group. System comprising a nozzle ( 100 ; 300 ; 400 ) according to one of the preceding claims and a fluid line ( 200 ) connected to the nozzle ( 100 ; 300 ; 400 ) connected is.

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