RU87142U1 - INSTALLATION FOR SIMULATING A FLIGHT OF AN AIRCRAFT UNDER A CLOUD - Google Patents

Abstract

1. Installation for simulating flight of an aircraft in a cloud, containing a device for receiving and storing ice crystals, containing a freezer and a device for preparing normalized ice crystals from an ice briquette located inside it, a container with a stirrer, a screw dispenser connected to the outlet of the container, and a source of dry cold air, while the device for preparing normalized ice crystals includes a tape drive on which the ice a briquette, an ice briquette pusher, an ice grinder, the ice grinder being made in the form of a cylindrical drum with cutting devices installed on it along its entire length, the geometry of which is selected with the possibility of crushing ice to normalized ice crystals having a certain normalized size in the limit of 1 mm, and a device for forming an air flow with ice crystals containing an ejector, one input of which is connected to the outlet through a screw batcher and a heat-insulated pipe container, and which receives the normalized ice crystals, and another input coupled to a source of air flow, heat-insulated nozzle installed at the outlet of the ejector, and air flow accelerates normalized ice crystals sent to the test object. ! 2. Installation according to claim 1, characterized in that the cutting devices are a set of cutters or circular saws. ! 3. Installation according to claim 1, characterized in that the nozzle is rotatable. ! 4. Installation according to claim 1, characterized in that the container is supplied

Description

The utility model relates to the field of mechanical engineering and can be used mainly in the aviation industry when conducting ground tests of aircraft subjected to icing in natural conditions.

A device for ground testing of objects of aviation equipment subjected to icing in natural conditions, including the test object, the air flow supplied, for example, from an air ramp, and ice crystals caught by the air flow (Antonov AN, etc. "Basics of calculation , design and testing of anti-icing systems for aircraft gas turbine engines ”, TsIAM, Moscow, 2001, pp. 100-102).

A device for ground testing of objects of aviation equipment subjected to icing (RF patent No. 2345345, publ. 2009), comprising a system of spraying devices, for example, working nozzles installed in a wind tunnel, an air flow formation system, an orientation and control system for working nozzles.

Known devices form an air flow with ice crystals in a wide range of sizes and do not allow testing the aircraft or its elements adequately to real flight in a cloud.

A feature of the flight of an aircraft in cloud conditions is that the real cloud contains ice inclusions in the form of ice crystals having a certain normalized size in the limit of 1 mm.

The technical task is to increase the adequacy of imitation of the real flight of an aircraft or its elements in a cloud.

The technical result is the formation of an air flow with normalized ice crystals to blow around the test object.

The problem is solved in that the installation for simulating the flight of an aircraft in a cloud, contains a device for receiving and storing ice crystals, containing a freezer and a device for preparing normalized ice crystals from an ice briquette located inside it, a container with a stirrer, a screw batcher connected to the outlet of the container, and a source of dry cold air, while the device for the preparation of normalized ice crystals includes tape the bottom on which the ice briquette is placed, the ice briquette pusher, the ice grinder, and the ice grinder is made in the form of a cylindrical drum with cutting devices installed on it along its entire length, the geometry of which is selected with the possibility of crushing ice to normalized ice crystals having a certain normalized size in the limit of 1 mm, and a device for forming an air flow with ice crystals, containing an ejector, one input of which through a screw batcher and heat insulators This pipeline is connected to the outlet of the container, and on which normalized ice crystals enter, and another entrance connected to the air flow source, a heat-insulated nozzle installed at the ejector outlet, accelerating the air flow and normalized ice crystals directed to the test object.

The container may be provided with a control flap installed in the outlet of the container.

Cutting tools are a set of cutters or circular saws.

It is advisable that the nozzle was made with the possibility of rotation.

The ejector has an outlet for condensate drain.

In the future, the utility model is illustrated by the description and drawings, in which:

figure 1 schematically shows a General view of the installation to simulate the flight of an aircraft in a cloud,

figure 2 shows a device for obtaining normalized ice crystals

figure 3 - a container for storing ice crystals and a screw dispenser.

figure 4 - shows an ejector with a nozzle.

An apparatus for simulating flight of an aircraft in a cloud environment comprises a device 1 for receiving and storing normalized ice crystals 19, according to a utility model, and a device 2 for generating an air flow with normalized ice crystals, according to a utility model, for blowing a test object 3 from a source 18 of the air stream (figure 1).

The device 1 includes a freezer 4 equipped with a cold generator 15, located inside the freezer 4, a device 5 for preparing normalized ice crystals from an ice briquette, a container 10 for storing normalized ice crystals with an agitator 11 and an outlet in which a shutter 12 is installed that controls the flow rate of samples taken from the container normalized ice crystals, a screw feeder 14, installed at the outlet of the container 10, and a source of cold dry air 13, which prevents melting and sticking e ice crystals. The mixer 11 may be mechanical in the form of an impeller mounted on the shaft 22 (figure 2). The damper 12 may block the outlet of the container 10 for storing ice crystals therein.

The device 5 for preparing normalized ice crystals includes a tape drive 7 on which an ice briquette 21 is placed, a pusher 8 of an ice briquette, an ice grinder 9

The ice crusher 9 (Fig. 3) is made in the form of a cylindrical drum with cutting devices 6 mounted on it along its entire length, made with the possibility of crushing ice to normalized ice crystals 19, having a certain normalized size in the limit of 1 mm.

Devices 6 can be a set of milling cutters or circular saws geometry which is selected with the possibility of crushing ice to normalized ice crystals 19 having a certain normalized size in the limit of 1 mm.

The cold generator 15 maintains conditions that exclude melting ice.

As the source 18 of the air flow can be used, for example, an air ramp.

The device 2 for forming an air flow with normalized ice crystals, blowing the test object 3, contains an ejector 17, one input of which is connected through the screw feeder 14 and the insulated pipe 16 to the output of the container 10, and to which the normalized ice crystals 19 enter, and another input connected with a source of air flow 18, a heat-insulated nozzle 20 installed at the outlet of the ejector 17, and accelerating the air flow with normalized ice crystals 19, sent to the test object 3. C ASW 20 is rotatable. The ejector 17 has an outlet for draining the condensate. Test object 3 may be elements of an aircraft.

A device for simulating the flight of an aircraft in a cloud during testing works as follows.

The belt-pulling mechanism 7, on which an ice briquette is placed using a pusher 8, moves this briquette to the ice grinder 9. The normalized ice crystals 19 obtained in the grinder 9 in the limit of 1 mm are sent to the container 10, where they are mixed with a mixer 11.

From the container 10, ice crystals are taken by auger batcher 14 and through a heat-insulated pipe 16 enter the ejector 17, where they are picked up by the air flow coming from the source 18. Next, the air flow and normalized ice crystals enter the nozzle 20, where the ice crystals together with the air stream are accelerated to speed corresponding to the flight speed of the aircraft in a cloud containing ice crystals, and are sent to the test object 3 using a rotary mechanism (not shown in the drawings).

Claims (5)

1. Installation for simulating flight of an aircraft in a cloud, containing a device for receiving and storing ice crystals, containing a freezer and a device for preparing normalized ice crystals from an ice briquette located inside it, a container with a stirrer, a screw dispenser connected to the outlet of the container, and a source of dry cold air, while the device for preparing normalized ice crystals includes a tape drive on which the ice a briquette, an ice briquette pusher, an ice grinder, the ice grinder being made in the form of a cylindrical drum with cutting devices installed on it along its entire length, the geometry of which is selected with the possibility of crushing ice to normalized ice crystals having a certain normalized size in the limit of 1 mm, and a device for forming an air flow with ice crystals containing an ejector, one input of which is connected to the outlet through a screw batcher and a heat-insulated pipe container, and which receives the normalized ice crystals, and another input coupled to a source of air flow, heat-insulated nozzle installed at the outlet of the ejector, and air flow accelerates normalized ice crystals sent to the test object. 2. Installation according to claim 1, characterized in that the cutting devices are a set of cutters or circular saws. 3. Installation according to claim 1, characterized in that the nozzle is rotatable. 4. Installation according to claim 1, characterized in that the container is equipped with a control flap installed in the outlet of the container. 5. Installation according to claim 1, characterized in that the ejector has an outlet for draining the condensate.