RU2143598C1 - Jet plant and process of its operation - Google Patents

Abstract

FIELD: heat engineering. SUBSTANCE: jet plant has jet apparatus with intake branch pipe, intake chamber, mixing chamber and nozzle. Plant is fitted with overflow pipe-line and throttle. Intake branch pipe is linked on side of its inlet to confuser section of overflow pipe-line. Mixing chamber communicates with diffuser section of overflow pipe-line. Throttle is positioned in overflow pipe-line. Axis of mixing chamber makes acute angle with axis of overflow pipe-line. Cool heat transfer agent is accelerated and part of it is carried into jet apparatus. The other part is throttled with formation of zone of reduced pressure along wall of diffuser conduit. Steam is fed into nozzle of jet apparatus in the capacity of hot heat transfer agent. Two-phase flow with its transformation to supersonic flow is formed downstream from nozzle with mixing of heat transfer agents. It is decelerated with transformation of two-phase flow in pressure jump to single-phase fluid flow. This flow is supplied to zone of reduced pressure and its boiling is organized in it with formation of two-phase supersonic flow which is decelerated with transformation to fluid flow of heat transfer agent in process of mixing with cool heat transfer agent. EFFECT: enhanced operational reliability of plant. 6 cl, 1 dwg

Description

 The present invention relates to the field of inkjet technology, mainly to inkjet installations used in water heating systems, as well as in other heat power systems.

 Known inkjet apparatus containing a nozzle, a mixing chamber, a diffuser and a receiving pipe (see, SU, copyright certificate, 1244392, CL F 04 F 5/02, 1986).

 From this copyright certificate 1244392, a method of operating an inkjet installation is also known, including supplying hot coolant to the nozzle, mixing it with cold coolant and supplying a heated stream to the heating system.

 This inkjet apparatus and method of its operation allow mixing hot and cold fluids and delivering the mixture to the consumer. However, the regulation of the operating mode of this jet apparatus is performed by throttling the hot coolant at the inlet to the nozzle, which reduces the efficiency of using the hot coolant due to sufficiently large hydraulic losses.

 The closest to the described by the technical nature and the achieved result is an inkjet installation comprising an inkjet apparatus with a receiving nozzle and coaxially mounted receiving chamber, mixing chamber and nozzle, the receiving nozzle connected to the receiving chamber (see DE, application, 2330502, class F 04 F 5/48, 1975).

 This application 2330502 describes a method of operating an inkjet installation closest to the invention, comprising supplying a hot coolant to the nozzle of the jet apparatus, its outflow from the nozzle and pumping out, due to this, cold coolant with their subsequent mixing and formation of a heated flow of coolant mixture on exit from the inkjet apparatus.

 In this installation and the method of its operation due to the bypass of the mixture of hot and cold fluids after the heat-consuming device, it is possible to control the operation mode of the jet installation. However, regulation is ensured by throttling the hot coolant at the nozzle exit and throttling the supply of the coolant mixture in the receiving chamber of the jet apparatus, which leads to large hydraulic losses and requires the use of a complex automatic control system for the operation of the jet apparatus, which reduces the reliability of the jet installation, and large hydraulic losses do not allow to obtain a sufficiently high efficiency.

 The problem to which the present invention is directed is to increase the heating efficiency of a cold coolant and increase the reliability of the installation.

 This problem is solved due to the fact that in an inkjet installation containing an inkjet apparatus with a receiving pipe and coaxially mounted with a receiving chamber, a mixing chamber and a nozzle, the receiving pipe being connected to a receiving chamber, the installation is additionally equipped with a confuser-diffuser (narrowing channel and then expanding channel along the flow) bypass pipe and throttling element, while the receiving pipe from the inlet side is connected to the confuser section of the bypass pipe, the chamber is Ia, the output side thereof, the diffuser portion communicates with the bypass duct, the throttle member is mounted in the bypass duct between its convergent portions and the diffuser and the mixing chamber axis with the axis of the bypass duct an acute angle.

 The throttling element can be installed at the entrance to the diffuser section of the bypass pipe, the confuser and diffuser sections of the bypass pipe can be communicated with each other through a cylindrical pipe, several jet devices can be connected to the bypass pipe, and each of these jet devices can be designed for different performance.

 In terms of the method of operation of an inkjet installation, the solution of the problem is achieved due to the fact that in the method of operation of an inkjet installation, which includes supplying a hot coolant to the nozzle of the jet apparatus, its outflow from the nozzle and pumping out, due to this, cold coolant with their subsequent mixing and the formation of a heated stream of a mixture of coolants at the outlet of the jet apparatus, and the coolant is dispersed and part of the coolant is removed from the acceleration zone to the jet apparatus, and the rest of the hour After acceleration, the cold coolant is throttled into a channel expanding along the flow (diffuser section) with the formation of a zone of reduced pressure along the channel wall, steam is fed into the nozzle as hot coolant, and during the mixing of steam with cold coolant, a two-phase flow is formed behind the nozzle exit section converting it into a supersonic flow, inhibit this flow with conversion in a pressure jump of a two-phase flow into a single-phase liquid heated flow of a mixture of coolants, this flow is fed into it undergoes reduced pressure and organize its boiling in it with the formation of a two-phase supersonic flow, which, when mixed with the cold coolant flow in the expanding channel, is inhibited with the conversion of the two-phase flow into the heated heat carrier fluid flow, which is supplied from the unit as intended.

 The implementation of the jet installation in the form of a bypass pipe and a jet device communicated with each other in the manner described above allows the heating process to be organized in such a way that the coolant directly through the bypass pipe with the smallest hydraulic losses enters the heat consumption system, and only strictly necessary is supplied to the mix with the hot coolant part of the coolant, and in fact a two-stage mixing is organized, i.e. first, a part of the cold coolant is mixed with the hot coolant in the jet apparatus, and then their mixture is mixed in the zone of the diffuser section of the bypass coolant with the rest of the cold coolant. This allows you to organize a continuously adjustable heating system for cold coolant.

 Important for the operation of the installation is the relative position of the elements of its design.

 The location of the axis of the mixing chamber at an acute angle to the axis of the bypass pipe allows to achieve minimal energy loss when mixing coolants.

 The flow of the coolant mixture from the jet apparatus to the diffuser section of the bypass pipe, together with the location of the throttling element between the confuser and diffuser sections of the bypass pipe, mainly at the inlet to the diffuser section, allows the coolant mixture to be supplied from the jet apparatus to the reduced pressure zone created by the throttle element along the diffuser wall section of the bypass pipeline. This allows you to achieve the effect of boiling flow at the point of flow of the mixture of coolants in the diffuser section of the bypass pipeline with the organization of a two-phase flow zone and the transition of the flow to a supersonic flow regime. The further flow in the diffuser channel and its interaction with the bulk of the cold coolant leads to inhibition of the flow, the conversion of the stream into a single-phase liquid flow and heating of the cold coolant due to the energy of the hot coolant. The described method of mixing the coolants in the zone of the diffuser section of the bypass pipeline can dramatically intensify the process of heat exchange between the coolants in a straight channel expanding along the flow, which can drastically reduce the loss of hydraulic energy. Moreover, the feedback process between the inlet confuser and outlet diffuser sections of the bypass pipe is organized, since an increase in pressure above the calculated one in the zone of the diffuser section will cause an increase in pressure in the confuser section, which in turn will cause an increase in the flow of cold coolant through the receiving pipe to the receiving chamber of the jet apparatus with increasing in it pressure and a corresponding increase in resistance to the outflow of hot coolant from the nozzle and, as a consequence, to a decrease in its outflow. This will lead to a decrease in the productivity of the jet apparatus and a decrease in the supply of the mixture of coolants from the jet apparatus to the diffuser section of the bypass pipe, which will lead to a decrease in pressure in it. Thus, the installation goes into self-regulation mode without using additional means of maintaining a given design mode of its operation.

 Another situation is possible in which the effect of self-regulation is manifested, and, consequently, the stable operation of the installation.

 If the steam supply pressure (and, consequently, its flow rate) from the nozzle of the jet apparatus decreases, the productivity of the jet apparatus for pumping out the coolant decreases. This will lead to a decrease in the flow of the mixture of coolants in the diffuser section of the bypass pipe as a result of reducing the impact on the flow of cold coolant flow of the flow of the mixture of coolants from the jet apparatus. A more intensive increase in pressure will take place in the diffuser channel, which will cause a decrease in the pressure drop across the throttling element with a decrease in the flow rate of cold coolant through it. Thus, with a decrease in the steam supply to the nozzle of the jet apparatus, the flow of cold coolant through the bypass pipe will automatically decrease while maintaining the heating of the cold coolant in a given temperature range.

 As the studies showed, the most effective operating mode is achieved when using water vapor as a hot heat carrier. Using it as a hot heat carrier allows you to organize the process of mixing hot and cold heat carriers with the creation of a two-phase flow zone and with the transition of the latter, due to a sharp decrease in the speed of sound in it, to a supersonic flow regime. In the process of deceleration of the flow in the mixing chamber, mainly confuser-cylindrical, in the pressure jump, the flow suddenly transforms from a two-phase to a single-phase, uniform in temperature, liquid flow. It was found that the maximum efficiency of the inkjet apparatus was achieved by communicating the receiving pipe with a bypass pipe in the area of its confuser section.

 One way to expand the range of use of the installation is to supply the installation with several inkjet devices, mainly of different capacities. This allows you to create installations stably working in a wide temperature range without compromising the efficiency of the installation.

 The drawing shows a schematically described inkjet installation.

 The inkjet installation comprises an inkjet apparatus 1 with a receiving pipe 2 and coaxially mounted a receiving chamber 3, a mixing chamber 4 and a nozzle 5, the receiving pipe 2 being connected to a receiving chamber 3. The installation further comprises a confuser-diffuser bypass pipe 6 and a throttling element 7. Receiving pipe 2 from the input side it is connected to the confluent (tapering along the flow of coolant) section 8 of the bypass pipe 6, the mixing chamber 4 is communicated from the output side with diffuser (expanding along in the coolant flow) section 9, a bypass conduit 6, the throttle element 7 is mounted in the bypass duct 6 between its convergent 8 and the diffuser 9 portions and the mixing chamber 4 with the axis of the overflow pipe 6 axis an acute angle α. The throttling element 7 can be installed at the entrance to the diffuser section 9 of the bypass pipe. The axis of the receiving pipe 2 may comprise a right angle β with the axis of the mixing chamber 4. The confuser and diffuser sections 8, 9 of the bypass pipe 6 can be communicated with each other by means of a cylindrical pipe 10. Several jet devices 1, which can have different capacities, can be connected to the bypass pipe.

 The method of operation of an inkjet installation is implemented as follows.

 Steam under pressure is supplied to the nozzle 5. At the same time, the bypass pipe 6 is connected to the source of cold coolant from the inlet to its confuser section 8. The steam flowing out of the nozzle 5 carries the cold coolant into the mixing chamber 4 from the bypass pipe 6 through the inlet pipe 2. As a result of mixing steam and cold coolant, the kinetic energy and steam heat are partially transferred to the latter, with the formation of a two-phase vapor-liquid flow behind the exit section of the nozzle 5. As a result of a decrease in the speed of sound in a two-phase flow, the latter switches to a supersonic flow regime with subsequent deceleration of the flow in the confuser channel of the mixing chamber 4 and the transition in the pressure jump of a supersonic two-phase flow into a subsonic single-phase liquid heated flow of a coolant mixture. In a predominantly cylindrical outlet section of the mixing chamber 4, the heated flow of the coolant mixture flows into the diffuser section 9 of the bypass pipe 6. At the same time, the coolant is accelerated in the confuser section 8 of the bypass pipe 6 and, flowing through the throttling element 7 into the diffuser section 9, forms along its wall in the zone of the outflow into it of the flow of the mixture of coolants from the jet apparatus 1 zone 11 low pressure. As a result, when a heated stream of a mixture of coolants flows to zone 11 of a reduced pressure, the latter boils with the formation of a two-phase vapor-gas-liquid stream with its transition, due to this, to a supersonic flow regime. As a result of the interaction of a two-phase flow with a cold coolant in the diffuser section, the supersonic flow is inhibited and switches to a subsonic flow regime. Moreover, in the process of the above-described transformations of a two-phase flow into a single-phase liquid flow, the hot heat carrier transfers part of its thermal and kinetic energies to the cold heat carrier. From the diffuser section 9, the heated flow of the mixture of coolants flows as intended to the consumer of thermal energy.

Claims (6)

 1. An inkjet installation comprising an inkjet apparatus with a receiving nozzle and a receiving chamber, a mixing chamber and a nozzle coaxially mounted, the receiving nozzle being connected to the receiving chamber, characterized in that the installation is further provided with a confuser-diffuser bypass pipe and a throttling element, while the receiving nozzle on the input side it is connected to the confuser section of the bypass pipe, the mixing chamber is in communication with the diffuser section of the bypass pipe, the throttling element getting into the bypass duct between its convergent portions and the diffuser and the mixing chamber axis with the axis of the bypass duct an acute angle.  2. Installation according to claim 1, characterized in that the throttling element is installed at the entrance to the diffuser section of the bypass pipeline.  3. Installation according to claim 1, characterized in that the confuser and diffuser sections of the bypass pipe are interconnected by means of a cylindrical pipe.  4. Installation according to claim 1, characterized in that several jet devices are connected to the bypass pipeline.  5. Installation according to paragraphs. 1 and 4, characterized in that the inkjet devices connected to the bypass pipe have different performance.  6. The method of operation of an inkjet installation, comprising supplying a hot coolant to the nozzle of the jet apparatus, its outflow from the nozzle and pumping out due to this cold coolant with their subsequent mixing and the formation of a heated stream of coolant mixture at the outlet of the jet apparatus, characterized in that it is cold the coolant is accelerated and a part of the cold coolant is removed from the acceleration zone into the jet apparatus, and the rest of the cold coolant after acceleration is throttled to expand along the flow towards the formation of double-pressure zones along the walls of this channel, steam is fed into the nozzle as a hot coolant, during mixing of steam with a cold coolant, a two-phase flow is formed behind the nozzle exit section to be converted into a supersonic flow, this flow is inhibited by conversion in a two-phase pressure jump flow into a single-phase liquid heated flow of a mixture of coolants, this flow is fed into the zone of reduced pressure and organize in it boiling with the formation of a two-phase supersonic flow, otorrhea during mixing with the flow of the cold coolant in the expanding channel to inhibit the conversion of the two-phase flow in a flow of heated liquid heat transfer medium which is fed from the unit to the destination.