RU135926U1 - NOZZLE FOR DELIVERY OF THE EXTINGUISHING COMPOSITION BY THE FIRST STATIONARY CARRIER BARRELS, INCLUDED IN THE KIT OF FIRE TRUCKS - Google Patents

Abstract

1. A nozzle for a fluid stream, comprising a housing having an inlet end adapted to be connected to a liquid supply device, and an outlet end, a screen that completely obscures the outlet end and is installed to form a gap between them for fluid passage, characterized in that the screen is installed motionlessly, the output end of the housing freely covers the sleeve with the possibility of its movement with a change in the gap for the passage of fluid, while the sleeve is kinematically connected to the output link of the screw-nut transmission, input whose link is connected to the servo drive. 2. Nozzles according to claim 1, characterized in that the output link of the screw-nut transmission is equipped with a handle.

Description

A utility model relates to nozzles for fluid flow in which a valve element forms part of an outlet. In particular, nozzles are installed on stationary fire monitors for the completion of fire tankers.

Known nozzles for fluid flow used in fire fighting (US patent No. 5312048, IPC B05B 1/32, publication 05/17/1994). The nozzle contains a cylindrical body with inlet and outlet ends. A sleeve is attached to the inlet end to connect the nozzle to a fluid supply source. The nozzle has a mechanism for regulating the pressure and flow rate of the liquid. This mechanism includes a screen (52) installed at the output end and completely obscuring this end, and means for longitudinally moving the screen (52) in the form of a spring (37) located between the screen (52) and the housing. Liquid is supplied to the inlet end of the nozzle. The fluid pressure on the back of the screen (52) moves it. The screen (52) moves away from the front part (97) of the neck insert (31) of the housing. Between the screen (52) and the housing, a gap (98) is formed. The movement of the screen (52) is balanced by a spring (37), acting to reduce the gap (98). With increasing pressure in the fluid supply system, the gap (98) increases, therefore, the fluid flow rate at the outlet end of the nozzle increases and vice versa.

In an emergency situation, a guaranteed regulation of the gap (98) is necessary for liquid to flow through it with different flow rates. For this, the formation of the gap (98) (98) should be independent of the characteristics of the fluid flow and the spring (37).

Adjustable nozzles are known in which the shape of the outgoing jet (and not the flow rate) is changed by moving a cylindrical sleeve having a cone-shaped expansion along the flow. The sleeve is mounted on the end of the nozzle and moves relative to said screen along the longitudinal axis of the nozzle. When the sleeve is advanced forward relative to the screen, a continuous jet with a zero spray angle is obtained. As the output end of the sleeve approaches the screen, the spray angle increases. The shape of the jet is controlled by a drive. So, at the beginning of column 9 of the description of US patent No. 8245790 (IPC A62C 2/00, publication 21.08.2012) it is said that there are adjustable nozzles in which the shape of the flow can change "using a drive mechanism or an electric drive similar to an electric drive, presented under No. 81185001 in the catalogs of Elkhart Brass Manufacturing Co. Inc., USA (Elkhart Brass Manufacturing Co., Inc. of Elkhart, Ind.) ... This drive can be remotely controlled by a control system (12), that is, the drive is a servo drive. According to columns 5 (at the end) and 6 (at the beginning) in the same place, the “control system (12) contains a control module (72), ... an input device (76) (keypad), buttons or a remote control device. The remote control device generates to the control module (72) signals about the initial position in order to select the desired ... nozzle shape "and, therefore, the shape of the jet exiting the nozzle. In the above catalogs, the servo drive under the number 81185001 is indicated by 18 in the figure and is described in the specification as a 12 V DC drive. In addition, in the catalogs of Elkhart Brass Manufacturing Co. Inc., USA, it is said about the Hydro-Chem Flex Operation nozzle that this nozzle is equipped with a direct current electric drive based on a ball screw pair to regulate the shape of the jet. “Nozzles can be adjusted in any position from direct flow to fog with a wide spray area. The required drive motor power is 11-14 (22-27) V DC. The current load on the drive motor is approximately 0.5 (0.25) A per second. The nozzles can be switched to manual control using a special nut. " The possibilities of regulating the shape of the jet using the above electric and manual drives are also mentioned, for example, in the catalogs of Elkhart Brass Manufacturing Co. Inc., USA, regarding X-Stream, 5000E & SM-10FE nozzles. However, in these nozzles, flow control is carried out according to the principle described in US patent No. 5312048, due to the spring mechanism, which works depending on the characteristics of the fluid flow passing through the nozzles. The drive control of the gap between the aforementioned screen and the output end of the nozzle, and, therefore, drive control of the fluid flow is not provided.

For the closest analogue (prototype) adopted nozzles for US patent No. 5312048, IPC B05B 1/32, publication 05/17/1994.

The utility model is aimed at improving the reliability of the nozzle in fire extinguishing devices.

The technical result in relation to the closest analogue is to provide in the nozzle the regulation of the gap for the passage of fluid and, therefore, the flow, regardless of the effect of the fluid flow on the screen of the nozzle.

For this, as in the closest analogue, the nozzles for the fluid flow comprises a housing having an inlet end adapted to be connected to the fluid supply device, and an outlet end, a screen that completely obscures the outlet end and is installed to form a gap between them for fluid passage .

In contrast to the closest analogue, the screen is fixed, the output end of the housing freely covers the sleeve with the possibility of its movement with a change in the gap for fluid passage, while the sleeve is kinematically connected with the output link of the screw-nut transmission, the input link of which is connected to the servo drive.

For manual regulation of fluid flow, the output screw-nut transmission link is equipped with a handle.

Nozzles shown in the figures with the following notation:

1 - housing

2 - input end

3 - output end

4 - screen

5 - tube

6 - tube rack

7 - screen rod

8 - the gap between the screen and the output end of the housing for the passage of fluid,

9 - sleeve

10 - servo

11 - nut transmission screw-nut "

12 - screw transmission screw-nut "

13 - plug

14 - an emphasis of a nut,

15 - handle.

The nozzle for the fluid stream contains a housing 1. The input end 2 of the housing 1 has a connecting place for connecting a fluid supply device (not shown in the figure), in particular, a stationary fire monitor included in the fire truck.

At the output end 3 of the nozzle, the screen 4 is fixedly mounted.

In a specific embodiment, for the fixed installation of the screen 4 there is a tube 5 with an internal thread mounted along the longitudinal axis of the housing 1 on three evenly spaced posts 6, resting on the inner walls of the housing 1. At the same time, a rod 7 with an external thread is fixedly attached to the center of the screen 4 , mating thread in the tube 5. The rod 7 of the screen 4 is screwed into the tube 5 and provides a fixed installation of the screen 4. The dimensions and configuration of the screen allow it to completely obscure the passage section of the output end 3.

Between the screen 4 and the output end 3 of the housing 1 there is a gap 8 for the passage of fluid. The dimensions of the gap 8 determine the flow rate of the liquid through the nozzles. The larger the size of the gap 8, the greater the flow rate and vice versa.

The output end 3 of the housing 1 covers the sleeve 9 with a loose fit on the housing 1, which allows the sleeve 9 to slide on the housing 1. Due to this, the sleeve 9 can move towards the screen 4 and vice versa. The sleeve 9 is installed so that its end when moving the sleeve 9 extends beyond the housing 1 and changes the gap 8.

The sleeve 9 moves under the action of the drive, including the transmission "screw-nut" and the servo drive 10 (shown conditionally). In this case, the input link of the screw-nut transmission is kinematically connected with the servo drive 10 (a servomotor with a control unit), and the output link of the screw-nut transmission is connected with the sleeve 9.

In a specific embodiment, the output shaft (not shown) of the servo drive 10 is connected to a nut 11, which in this case is an input link of a screw-nut transmission. The screw 12, which is the output link of the screw-nut transmission, is connected to the sleeve 9 by means of a yoke 13. The yoke 13 secures the screw 12 from rotation. The nut 11 is fixed from longitudinal movement along the screw 12 due to the stop 14 on one side and the plug 13 on the other side.

When the servo drive 10 is turned on, the rotation from its shaft is transmitted to the nut 11. The rotation of the nut 11 is converted into the translational movement of the screw 12 and, consequently, into the translational sliding of the sleeve 9 along the housing 1. In this case, the end of the sleeve 9 may approach or move away from the screen 4 depending on the direction of rotation of the servomotor in the servo drive 10. Accordingly, the gap 8 for the passage of fluid and fluid flow decreases or increases.

A handle 15 can be mounted on the nut 11 for manual control of the flow, for example, in case of a power failure of the servo drive 10.

Thus, in comparison with the closest analogue, the gap 8 is regulated for the passage of liquid and, consequently, the flow rate, regardless of the effect of the liquid flow on the nozzle screen, which increases the reliability of the nozzle in fire extinguishing devices.

Claims (2)

1. A nozzle for a fluid stream, comprising a housing having an inlet end adapted to be connected to a liquid supply device, and an outlet end, a screen that completely obscures the outlet end and is installed to form a gap between them for fluid passage, characterized in that the screen is installed motionlessly, the output end of the housing freely covers the sleeve with the possibility of its movement with a change in the gap for the passage of fluid, while the sleeve is kinematically connected to the output link of the screw-nut transmission, input whose link is connected to the servo drive. 2. Nozzles according to claim 1, characterized in that the output link of the screw-nut transmission is equipped with a handle.

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