SU1092306A1 - Water-jet elevator - Google Patents

Abstract

1. A WATER ELEVATOR containing a nozzle, a mixing chamber regulating a damper installed inside the nozzle and fixed at the end of the bellows with a spring, characterized in that it is equipped with a dilatometer with a valve placed in the mixing chamber and a pulse tube to increase reliability in operation connecting the bellows to the valve. 2. An elevator, characterized in that the pulse tube is provided with a temperature-sensitive element, and the dilato-meter is placed in a heat-conducting case.

Description

3 S 7 The invention relates to devices for mixing liquids, namely adjustable inkjet devices. A water jet elevator is known, including a nozzle, a displacement chamber, an adjusting valve and a drive device 1. The closest to the proposed technical solution is a water elevator comprising a water jet nozzle, a displacement chamber, an adjusting valve installed inside the nozzle and fixed on the end of the bellows with a spring, the internal cavity of which is connected to the water-jet nozzle 2. The disadvantage of this device is insufficient reliability of operation. The aim of the invention is to increase the reliability of operation. The goal is achieved by the fact that a water-jet elevator containing a nozzle, a mixing chamber, an adjusting valve installed inside the nozzle and attached to the end of the bellows with a spring, is equipped with a dilatometer with a valve placed in the mixing chamber, and a pulse tube connecting the bellows with valve. The impulse tube is filled with a temperature-sensitive element, and the dilatometer is placed in a heat-conducting case. FIG. 1 is a diagram of the proposed device; in fig. 2 - the same, option. The device contains a mixing chamber 1 with an input 2 and an output 3 cavities, a water-jet nozzle 4, in the cavity of which a conical flap 5 is placed, fixed on the movable end of the bellows 6 with a spring 7, the internal cavity of which through the hydraulic resistance 8, the receiving chamber 9 and the filter element 10 communicates with the internal cavity of the water jet nozzle. The bellows cavity through the channel 11 and the pulse tube 12 simultaneously communicates with the pre-heating cavity 13 of the dilatometric temperature sensor with the nozzle 14 and the flap 15. rigidly connected with Invar rod 16 installed inside the brass tube 17, washed with water at the exit of the elevator and connecting the back of the cavity 18 through the hole 19 with the output cavity of the Venturi tube. In a water-jet elevator (Fig. 2), a pulse tube 12 is connected to a thermo-sensitive element 20 in the form of, for example, a coil installed in an outdoor air zone outside the room. The thermosensitive element, in turn, is connected to impulse cavity 13 by impulse piping 21, casing 22 is connected to drainage hole 23 washed by water at the exit of the elevator. Water Elevator (Fig. 1) works as follows. The heat carrier jets out of jet 4, due to the injection of bias 1 into the chamber, carries the medium out of the inlet cavity 2 and, shifting with it, enters the output cavity 3, driving the mixed medium. As the temperature of the medium being pushed in the exit cavity 3 increases, the brass tube 17 expands through the Invar rod 16 with the shutter 15 covers the nozzle 14. The pressure of the working medium in the cavity of the bellows 6 increases due to the leakage through the hydrothrottle 8, and the spring 7 with the shutter 5 covers the water jet nozzle 4. The feed of the admixed medium into the mixing chamber is reduced. When the mixed medium is cooled in the outlet cavity 3, the nozzle 14 is opened by the shutter 15, and the reverse occurs. The medium from the cavity of the dilatometric tube 17. The temperature sensor is vented into the output cavity 3 through the opening 19. Thus, the temperature of the mixed medium is maintained near the set value and the negligible amount of waste water in the regulator with the sensor is not lost, but is vented into the heating system. The cross-sectional area of the receiving channel 9 is made two orders of magnitude larger than the cross-sectional area of the hydraulic resistance 8, which ensures high quality of water purification by the filter element 10, reliably protecting the hydrothrottle from clogging. The water elevator (Fig. 2) in the heating system works in the same way. and with the only difference that the water coming from the bellows to the temperature sensor through the heat exchanger is cooled under the action of outside air and, flowing through the temperature sensor, adjusts its setting depending on the outside air temperature and then drains through the drain hole 23 into the cavity 3 This ensures that the water-heating elevator maintains the heating schedule. The temperature sensor is adjusted by setting the gap between the nozzle 14 and the valve 15, and the desired slope of the heating curve can be maintained by selecting the heat transfer coefficient of the node 20.

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Claims (2)

1. A water-jet elevator comprising a nozzle, a mixing chamber, a regulating flap installed inside the nozzle and fixed at the end of the bellows with a spring, characterized in that, in order to increase reliability in operation, it is equipped with a dilatometer with a valve located in the mixing chamber and a pulse a tube connecting the bellows to the valve. 2. Elevator, characterized in that the impulse tube is equipped with a heat-sensitive element, and the dilatometer is placed in a heat-conducting housing.