DK163966B - Nozzle for a spray - Google Patents

Description

DK 163966 B

The invention relates to a nozzle for use in a syringe, in particular for spraying an airplane with a deicing fluid, which syringe includes a pressure source for a medium to be sprayed.

Spraying of an airplane with a de-icing fluid is usually done immediately, ie. minutes before takeoff to ensure the maximum de-icing effect. This means that a nozzle for use with a jet for spraying an airplane should have a great deal of movement in order to be able to carry out the necessary working movements for the proper distribution of the deicing fluid in a very short time.

According to the invention, this object is achieved by the measures specified in the characterizing part of claim 1.

These mean that the nozzle is constructed around a main tube which encloses an inner tube and is axially displaceable along it which is externally enclosed by an axially displaceable sleeve and which together with both the inner tube and the sleeve, limit pressure spaces which can be connected to the source for 20 pressure medium for controlling the axial displacement of the parts relative to each other. An embodiment of a control mechanism usable in accordance with the invention is given in claim 2.

This in turn means that the nozzle according to the invention is made up of very few parts, which is why it becomes light in weight and quickly movable and controllable to control both the amount of liquid ejected and the spreading form of the ejected liquid jet, as further explained in the description of an embodiment. Therefore, the nozzle is particularly well suited for carrying out the above-described work, because of its low weight and its quick adjusting capabilities, it allows an all-round spraying of deicing aircraft with deicing fluid in a matter of minutes. For example, the work can be managed from a work platform where an operator is located, 35 who must also perform other essential tasks, for example, control the working postures of the platform and also a mechanism supporting the mouthpiece.

2

DK 163966 B

The invention will now be explained in more detail with reference to the drawing, in which fig. 1 is a partial sectional side elevational view of an embodiment of a nozzle according to the invention; and FIG. 2 is a schematic diagram of a hydraulic system for controlling a syringe.

The nozzle consists of a screw 80 with an internal thread 81 for fastening the nozzle to a pipe bend. To this screw 80, a main pipe 83 is fixedly fixed by means of a thread 10 82 and, furthermore, to the screw 80 a valve body 84 is secured by a screw 85. The valve body 84 is connected to the screw 85 by means of a valve stem consisting of of a round portion 86 and a flat portion 87. Around the valve shaft 86, 87, an inner tube 88 is displaceably disposed within the main tube 83 and the valve shaft is guided therein due to the flat portion 87 of the valve shaft having substantially the same width as the diameter of the inner tube 88, and further, the flat portion 87 carries spacers 89 on which the inner tube 88 can slide.

The inner tube is provided with an outer, circumferential cam 90, and between this and the screw 80 is provided a compression spring 91. At the opposite side of the cam 90 there is a circumferential compression chamber 92 and this is sealed by two circumferential packing rings 93 and 94 located in grooves 25 in the inside of the main tube 91 and the outside of the cam 90, respectively. To this pressure chamber 90, a pressure access 95 is provided.

It will be appreciated that when the pressure chamber 90 is pressurized, the inner tube 88 will displace against the action of the spring 91, and below this, the left end of the inner tube 30 88 will release its abutment against the valve body 84, thereby creating an outlet for spray liquid.

A sleeve 96 is arranged around the main tube 83.

This is slidably disposed on the main tube 83 in the left direction of FIG. 1 against the action of a spring 97 disposed about the main pipe 83, one end of which rests against a cam 98 thereon, and the other end of which rests against a spring ring 99 attached to the end of the sleeve 96.

3

DK 163966 B

To the left of the cam 98 is provided a circumferential pressure chamber 100 which is sealed to the sides by means of two packing rings 101 and 102. There is provided a pressure access 103. This pressure chamber is understood to pressurize the pressure space 5 100. the bushing will be moved to the left in FIG. First

The end of the sleeve is formed with an outwardly extending cone surface 105 and further carries a swirl ring 106. The swirl ring 106 is pivotally mounted in an inner groove in the sleeve and is provided with oblique or helical slots.

From the explanation given above, it will be appreciated that if the pressure inlet 103 is pressurized, the bushing will be displaced to the left in FIG. 1, and thereby 15 the vortex ring 106 will project into the beam which would otherwise be sprayed cone-shaped between the end of the inner tube 88 and the valve body 84. Thereby, this cone-shaped beam will be split or atomized. Moving the sleeve even further to the left, it will be seen that the inside of the sleeve will project beyond the end of the inner tube 88, thereby ceasing the nebulization effect, and instead the sleeve's interior will transform the otherwise cone-shaped beam into a largely cylindrical beam.

The nozzle is shown schematically in FIG. 2 with the two pressure-25 approaches 95 and 103.

In FIG. 2 shows how the jet mold control sleeve 96 is controlled by varying the pressure to the pressure chamber 100 through the pressure inlet 103. The pressure inlet 103 is coupled to a hydraulic pump 108 over a quantity control valve 30 123, and in front of which is a drainage line in which a pressure control valve 124 is inserted. which branch conduit leads to a reservoir 114. It will be understood that the pressure chamber 100 is not to be fed with any very large quantity, but only to the extent that the volume of the pressure chamber increases during the regulation, whereas the pressure is of great importance. By means of the volume controller 123, which is adjustable and configured in a manner known per se, a 4

DK 163966 B

relatively small flow rate through the quantity regulator 123. By now regulating the resistance more or less by the pressure control valve 124, this will more or less throttle the pressure delivered by the quantity regulator 123.

In the case of heavy throttling, that is, when the valve 124 is approximately closed, the pressure inlet 103 will be fed at a high pressure, and consequently the sleeve 96 will assume the position explained in the foregoing far left in FIG. 1. However, if the pressure control valve 124 is opened, this throttle 10 will decrease, whereby the inlet pressure to the pressure inlet 103 will decrease, and the bushing will move infinitely to the right in FIG. 1. Accordingly, in this way conversion of the beam forms can be provided as explained above, and it will be appreciated that the volume regulator 123 and pressure regulator 124 may be arranged in a cabin to be operated by the present operator.

The control of the mouthpiece opening and closing is also illustrated in FIG. 2, from which it will be seen that the pressure supply 95 is connected to the hydraulic pump 108 in the same way 20 as is the case to the pressure supply 103, the pressure supply 95 being controlled over a quantity control valve 126 and a pressure control valve 127 which is designed and operates in the same manner as previously described, as far as the quantity control valve 123 and the pressure control valve 124. In other words, the pressure applied to the pressure supply 95 can be regulated from a high value, namely by vigorous throttling in the valve 127 and to a low value, namely by small throttling in the valve. 127. In the latter case, the flow through the valve 127 will, after all, be large with correspondingly small resistance 30 and consequently the pressure applied to the pressure supply 95 will decrease.

From the foregoing explanation, it will be understood that the greater the pressure applied to the pressure chamber 92, the more the inner tube 88 will move and the greater the amount of spray liquid will be ejected per minute. unit of time.

In order to control the start and stop of the outflow through the nozzle, the pressure inlet 95 is connected to the reservoir 114 over a conduit into which an electric 5 is inserted.

DK 163966 B

controlled off-on valve 128. This is also of a kind known per se, and it should therefore only be mentioned that it is normally open and thus relieves the pressure supply 95. On the contrary, it is actuated to a closed position by means of 5, the pressure control valve 126 and the pressure control valve 127 set the pressure to propagate to the pressure inlet 95 and an opening will occur. It will be appreciated that valve 128 can be controlled by a simple pushbutton, which may also be located in the cabin for operating the belt operator.

Claims (2)

6 DK 163966 B PATENT CLAIM. A nozzle for use in a syringe, in particular for spraying an airplane with a deicing fluid, which syringe includes a pressure source for a medium to be sprayed, characterized in that the nozzle (40) consists of a head tube (83) which is connected to the syringe pump, in which the main pipe (83) is slidably mounted against the action of a spring (91) an inner tube (88) having at one end a seat for cooperation with a valve body (84) which is held relative to the main pipe (83), where between the main pipe (83) and the inner pipe (88) is provided a pressure chamber (92) which is connectable to a pressure source (108) for moving the inner pipe (88) in a direction away from the valve body. (84), on which head tube (83) is further slidably mounted against the action of a spring (97) a sleeve (96) for controlling the shape of the jet emitted by the nozzle (40), between which sleeve (96) and the main pipe (83) providing a pressure a chamber (100) which is connectable to the pressure source (108) for moving the bushing relative to said one end of the main pipe, which bushing at its end has an atomizer ring (106). Nozzle according to claim 1, characterized in that the two pressure chambers (92 and 100) are connected to the pressure source (108) over each adjustable quantity control valve 25 (126, 123) and that between the output side of each quantity of control valve and the associated pressure chamber is branched into a conduit (114) leading to a pressure control valve (127 and 124, respectively) to which the pressure space (92) provided between the main tube 30 (83) and the inner tube (88) is connected. with the reservoir (114) over an off-valve (128).