EP1685894A2 - Venturi mixing nozzle - Google Patents

Abstract

In a Venturi mixing nozzle with a housing (1), a fluid inlet section (2), a fluid outlet section, a flow region for a first fluid, a first pressure opening (P1) in the housing and a second pressure opening (P2) at the narrowest part of the Venturi nozzle in the housing, at least one transverse tube (3) in the fluid inlet section is connected with the first pressure opening and has an opening (Oe) lying in the flow region for the first fluid. An independent claim is included for a method for operating a mixing nozzle of this type (in which the first fluid flows from the fluid inlet section to the fluid outlet section), involving feeding part of the first fluid into the transverse tube (3) via the opening (Oe), to create a congestive pressure in the tube which at least balances the reduced pressure created by the flow velocity of the first fluid at the first pressure opening.

Description

Fig. 1 shows an example of a venturi mixing nozzle according to the prior art. Among other things, such Venturi mixing nozzles are used to produce a mixture of a first, flowing fluid and a second fluid. In numerous applications, such as heating technology, the ratio of the fluids should remain constant even with a change in the fluid quantity or the flow rate. For this purpose, the Venturi mixing nozzle through which a first fluid flows is provided with a first pressure opening at a fluid inlet section 2 and a second pressure opening at a narrowest point D of the Venturi mixing nozzle, with negative pressures P1, P2 occurring at these pressure openings. The pressure ports are in communication with a second fluid supply device designed as a valve. Based on the differential pressure P2 - P1 of these negative pressures P1, P2, it is possible to determine the amount of the first, flowing fluid and to supply the required amount of the second fluid to be mixed with the first fluid.

Ideally, Venturi mixing nozzles are designed such that the pressure P1 at the first pressure port is approximately zero. However, in the case of large Venturi mixing nozzles under certain operating conditions, the pressure P1 at the first pressure opening may drop, ie to a negative pressure P1, which impairs the control of the supply of the second fluid, since the smaller differential pressure P2-P1 causes the pressure to decrease Capacity and the modulation range of the valve can be reduced. The negative pressure P1 at the first pressure opening may be up to 30% of the negative pressure P2 at the second pressure opening.

It is the object of the invention to provide a Venturi mixing nozzle in which a differential pressure corresponds at least to the value of the negative pressure at the narrowest point of the Venturi mixing nozzle.

The object is achieved by a venturi mixing nozzle according to claim 1 or by a method according to claim 10.

According to the invention, a device for generating a dynamic pressure in a fluid inlet portion of a venturi mixing nozzle is provided. Advantageously, the device for generating a back pressure in the form of at least one cross tube in a fluid inlet portion of a Venturi mixing nozzle is executed. The cross tube has an opening in a flow area of a first fluid flowing from the fluid inlet portion toward a fluid outlet portion through the venturi mixing nozzle. In addition, the cross tube according to the invention is in communication with a first pressure opening in a housing of the Venturi mixing nozzle. At the narrowest point of the venturi mixing nozzle is a second pressure port through which a second fluid to be mixed with the first fluid is introduced into the venturi mixing nozzle.

Both pressure ports are connected to a second fluid supply means such that the supply amount of the second fluid is controlled by a differential pressure. Preferably, the supply means for the second fluid is designed as a valve.

A portion of the first fluid flowing through the venturi mixing nozzle is directed through the opening into the cross tube in such a way that a back pressure arises in the cross tube. Of the Back pressure in the cross tube is used to compensate for a resulting at the position of the first pressure opening negative pressure. This keeps the differential pressure at its maximum value, allowing full capacity and modulation range of the valve.

The orifice is adjacent to the flow of the first fluid such that a portion of the first fluid is directed into the cross tube. Advantageously, the opening is therefore directed directly against the flow direction of the first fluid.

An inner diameter of the cross tube preferably corresponds to 0.02 times to 0.3 times the diameter at a narrowest point of the fluid inlet portion, ie the smallest diameter of the Venturi mixing nozzle, while a distance of the cross tube from the narrowest point to 0 times 3 times the smallest diameter.

By varying the inner diameter and the distance of the cross tube, the pressure at the first pressure opening is adjustable so that the differential pressure is greater than the value of the negative pressure at the second pressure opening. If the cross tube is arranged at the position of the smallest diameter, it is even possible to double the pressure difference and increase the modulation range from 1: 6 to 1: 8.5. As a result, the amount of second fluid can be increased by as much as 41% as compared to a cross-tube Venturi mixing nozzle.

According to one aspect of the invention, the opening is provided in a central portion of the cross tube.

According to a second aspect, the cross tube has a free end, wherein the opening in the free end of Cross tube is formed. In particular, the free end has a curved portion, wherein the opening is directed against the flow direction of the first fluid. In addition, the free end of the cross tube is located substantially on the center axis of the Venturi mixing nozzle.

• Fig. 1 eine aus dem Stand der Technik bekannte Venturi-Mischdüse;
• Fig. 2 eine Venturi-Mischdüse mit einem Querrohr gemäß einem ersten Ausführungsbeispiel; und
• Fig. 3 eine Venturi-Mischdüse mit einem Querrohr gemäß einem zweiten Ausführungsbeispiel.

For a better understanding of the invention, the following description of preferred embodiments is used. It shows:

• Figure 1 is a known from the prior art Venturi mixing nozzle.
• 2 shows a Venturi mixing nozzle with a cross pipe according to a first embodiment; and
• Fig. 3 is a Venturi mixing nozzle with a cross tube according to a second embodiment.

Fig. 2 shows a Venturi mixing nozzle according to a first embodiment. This Venturi mixing nozzle essentially consists of a fluid inlet part 2 with a decreasing inside diameter which is received in a housing 1 starting from one end side. A first fluid enters the venturi mixing nozzle at the same end face and flows through it.

The housing 1 has a receiving space for receiving the fluid inlet portion serving as Fluideinlasabschnitt 2, wherein an inner diameter of the housing 1 expands adjacent to the receiving space in the flow direction of the first fluid. This area of the housing 1 is defined as a fluid outlet section.

The inner diameter of the fluid inlet part 2 decreases in the flow direction of the first fluid to be in the End area of the receiving space to have the smallest diameter D. In this case, the smallest diameter D of the fluid inlet part is smaller than the smallest diameter of the fluid outlet section. There is a gap between the fluid inlet part 2 and the fluid outlet part, the gap communicating with a valve provided outside the venturi mixing nozzle and not shown in the figures as a second fluid supply means through a second pressure opening in the housing.

A first pressure port P1 is provided in the flow direction of the first fluid before the second pressure port P2 in the wall of the housing 2 and also communicates with the valve for supplying the second fluid. In the area of the pressure opening P1, a cross tube 3 guided from the wall of the housing to the opposite wall area is provided such that a connection from the pressure opening P1 to the interior of the fluid inlet part 2 is possible only through the cross tube 3. The cross tube 3 lies in a plane of symmetry of the Venturi mixing nozzle, as shown in the figures.

In a central portion of the cross tube 3, a directed against the flow direction of the first fluid opening Oe is provided. The center of the opening Oe is located on the symmetry axis of the Venturi mixing nozzle.

Fig. 3 shows a second embodiment of the invention. Since the Venturi mixing nozzle according to the second embodiment except the cross pipe 4 is the same as the Venturi mixing nozzle according to the first embodiment, the same reference numerals are used for identical components, and a description of the same components will not be repeated.

The cross tube 4 is also provided in the region of the first pressure port P1 such that a connection from the first pressure opening P1 to the interior of the fluid inlet part 2 is possible only through the cross tube 4.

In contrast to the cross tube 3 of the first embodiment, however, the cross tube 4 has a free end which simultaneously forms the opening Oe. The opening Oe thus corresponds to a circular area whose diameter corresponds to the inner diameter of the cross tube 4. In addition, the cross tube 4 in the region of the free end on a curved counter to the flow direction 90 ° section, so that the plane of the opening Oe forming circular surface is perpendicular to the axis of symmetry of the Venturi mixing nozzle, wherein the center of the circular surface on the axis of symmetry of the Venturi -Mix nozzle is located.

As it flows through the first fluid, a negative pressure which depends on the flow velocity of the first fluid is produced at the position of the transverse tube. This negative pressure is compensated for by the dynamic pressure arising at the opening Oe in the tube such that the total pressure at the pressure port P1 corresponds essentially to zero. As a result, the pressure difference between the second pressure port P2 and the first pressure port P1 substantially corresponds to the second negative pressure P2. This makes it possible to utilize the full capacity and the entire modulation range of a differential pressure controlled valve serving as a second fluid supply device.

Claims (10)

Venturi mixing nozzle having a housing (1), a fluid inlet portion (2), a Fluidauslassabschnitt, a flow area for a first fluid, a first pressure port (P1) in the housing (1), and provided at the narrowest point of the Venturi mixing nozzle second pressure port (P2) in the housing (1), characterized in that at least one cross tube (3) is provided in the fluid inlet section (2) of the Venturi mixing nozzle, which is connected to the first pressure port (P1) and one in the flow region of the first fluid lying opening (Oe). Venturi mixing nozzle according to claim 1, characterized in that the opening (Oe) is directed against a flow of the first fluid, which flows through the Venturi mixing nozzle from the fluid inlet portion (2) in the direction of a Fluidauslassabschnitts. Venturi mixing nozzle according to claim 1 or 2, characterized in that an internal diameter (s) of the cross tube (3) corresponds to 0.02 times to 0.3 times the diameter (D) at a narrowest point of the fluid inlet portion (2). Venturi mixing nozzle according to claim 1 to 3, characterized in that a distance (a) of the cross tube (3) from the narrowest point corresponds to 0 to 3 times the diameter (D) of the narrowest point. Venturi mixing nozzle according to claim 1 to 4, characterized in that more than one cross tube (3) is provided. Venturi mixing nozzle according to claim 1 to 5, characterized in that the opening (Oe) is provided in a central portion of the cross tube. Venturi mixing nozzle according to claim 1 to 5, characterized in that the opening (Oe) is formed in a free end of the cross tube (3). Venturi mixing nozzle according to claim 7, characterized in that the free end has a curved portion. Venturi mixing nozzle according to claim 7 to 8, characterized in that the free end of the cross tube is arranged substantially on the central axis of the Venturi mixing nozzle. A method of operating a Venturi mixing nozzle, comprising a housing (1), a fluid inlet section (2), a fluid outlet section, a first fluid flow section, a first pressure port (P1) in the housing (1), and one at the narrowest point the Venturi mixing nozzle provided second pressure port (P2) in the housing (1), wherein the first fluid flows from the fluid inlet portion (2) to the Fluidauslassabschnitt, characterized in that a portion of the first fluid by means of a in one with the first pressure port (P1) connected to the cross tube (3) provided in the cross tube (3) is guided in order to generate a back pressure in the cross tube (3), which at least compensates for a negative pressure resulting from the flow velocity of the first fluid at the first pressure port (P1).

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