RU2649554C1 - Equipment heat utilization plant - Google Patents

Abstract

FIELD: ventilation.

SUBSTANCE: invention relates to ventilation and air conditioning with regenerative heat recovery units. In a heat recovery device for equipment containing a casing, a tray, a freezing protection system, a two-stage contact heat exchanger with a nozzle, a cooling system with a heat exchanger, the nozzle is made of a compact thin-film corrugated film with the thickness of 0.4…0.8 mm, herewith molded sheets of the nozzle are connected by glue, and the nozzle surface is alternating channels of a triangular shape that are inclined to the axis of the coolant draining according to the counterflow scheme: one sheet at the angle of +30°, the other one glued on it – at -30°, and along the length the channels are made with U-shaped corrugation, nozzle of the irrigation system comprises a body, a fitting and a coaxially arranged swirling insert with an external helical thread and an expanding conical hole inside, wherein the fitting has a cylindrical inlet opening connected to a diffuser, which is made axially symmetric in the body, and in the lower part of the body there is a nozzle arranged axially symmetric to the body and having a two-stage and coaxial to the swirling insert diffuser, the first stage of the diffuser is a continuation of the expanding conical hole made inside the swirling insert, which is made from a wear-resistant material, and the second stage of the diffuser is a continuation of its first stage, while on its inner conical surface a screw-like thread is made, herewith the conical surface with the screw-like thread of the second stage of the diffuser is made perforated, and in the lower part of the body, coaxial to it, a cylindrical shell is fixed, on which a flow divider is arranged in the form of at least two rods located obliquely to the axis of the nozzle and connected to each other in the lower part, to which a vertically disposed rod is attached, onto which there is a vortex made in the form of a cone with helical blades enclosing the rod with a clearance and resting in the lower part on a thrust located horizontally and perpendicular to the rod.

EFFECT: increased efficiency of heat recovery of the water from process equipment.

1 cl, 2 dwg

Description

The invention relates to ventilation and air conditioning with regenerative heat exchangers.

The closest technical solution to the claimed object is a supply and exhaust unit with a regenerative heat exchanger rotating in a horizontal plane according to RF patent No. 2282793, F24F 5/00, 1987 (prototype), comprising a housing, a pallet, a frost protection system, a two-stage contact heat exchanger with nozzle; cooling system with heat exchanger.

The disadvantage of the prototype is the relatively low efficiency.

The technical result is an increase in the efficiency of heat recovery of water from technological equipment.

This is achieved by the fact that in a heat recovery installation of equipment containing a housing, a pallet, an anti-freeze protection system, a two-stage contact heat exchanger with a nozzle, a cooling system with a heat exchanger, the nozzle is made of a compact thin-film corrugated film with a thickness of 0.4 ... 0.8 mm, and molded nozzle sheets are connected by glue, and the nozzle surface is alternating channels of a triangular shape, which are inclined to the axis of flow of the coolant in a countercurrent pattern: one sheet at an angle of + 30 °, another th pasted on it is 30 °, and along the length the channels are made with a U-shaped corrugation, the nozzle of the irrigation system contains a body, a nozzle and a coaxially located swirl insert with an external screw-shaped thread and an expanding conical hole inside, with an inlet cylindrical hole the hole connected to the diffuser, made axisymmetrically in the body, and in the lower part of the body is located axisymmetrically to the body of the nozzle, which is made with a two-stage, and coaxial swirl insert, diffuser, the first step diffuser is a continuation of the expanding conical hole made inside the swirl insert, which is made of wear-resistant material, and the second stage of the diffuser is a continuation of its first stage, while a screw-shaped thread is made on its inner conical surface, and a conical surface with a screw-shaped thread of the second stage of the diffuser made perforated, and in the lower part of the body, coaxially to it, a cylindrical shell is fixed, on which a flow divider is installed, made in the form of at least two rods arranged obliquely to the axis of the nozzle, interconnected in the lower part, to which a vertically arranged rod is attached, on which a swirl is mounted, made in the form of a cone with screw blades, covering the rod with a gap and resting on lower part on the stop, located horizontally and perpendicular to the rod.

In FIG. 1 shows a General view of the proposed installation, in FIG. 2 is a diagram of a nozzle of an irrigation system of a two-stage contact heat exchanger.

The heat recovery unit of the equipment is equipped with a frost protection system 2 and has an increased irrigation density of the lower stage of a two-stage contact heat exchanger 1 with a nozzle and a nozzle irrigation system, while the nozzle is made of a compact, thin-film and corrugated vinyl-plated calendared film with a thickness of 0.4 ... 0.8 mm which is safe to use, flame-resistant and does not emit harmful substances at temperatures up to 170 ° C. Individual molded nozzle sheets are glued together with glue. The nozzle surface is alternating channels of a triangular shape, which are inclined to the axis of flow of the coolant in a countercurrent pattern: one sheet at an angle of + 30 °, the other glued to it - 30 °. The length of the channels is made with a U-shaped corrugation (not shown in the drawing). Water from the cooling system through pipeline 6 enters the heat exchanger 4, where it gives its heat to heat the water coming from the pan 3 to the heat exchanger 1 and the frost protection system 2, and then returns through the pipeline 5 to the cooling system.

The nozzle irrigation system of the two-stage contact heat exchanger 1 includes a nozzle (Fig. 2), which contains a housing 11 and coaxially located and rigidly connected to it in the upper part of the nozzle 12 with an inlet cylindrical hole 13 connected to the diffuser 14, made axisymmetrically in the housing 11 . In the lower part of the casing is located axisymmetrically to the casing 11 of the nozzle 15. The nozzle 15 is made with a two-stage and coaxial insert-swirl 16 diffuser, while the first stage 20 of the diffuser is a continuation of the expanding horse eskogo openings 17 formed within the insert-swirler 16 and second stage diffuser 21 is an extension of its first stage 20, and on its inner conical surface formed helical thread (shown in the drawing on).

The swirl insert 16 is located in the central cylindrical hole 18 of the housing 11 and has external peripheral helical threaded channels 19, and inside the swirl insert 16, an expanding conical hole 17 is coaxially provided for supplying fluid from the cylindrical hole 13 made in the fitting 12. The swirl insert 16 fixed in the lower part of the housing 11 through the nozzle 15. The insert swirl 16 is made of wear-resistant material. The conical surface with a screw-shaped thread of the second stage 21 of the diffuser is perforated.

The nozzle for spraying liquid works as follows.

The fluid enters the housing 11 through the fluid supply channel 13 in the nozzle 12, and then into the central cylindrical hole 18. The fluid begins to swirl in the peripheral channels 19 of the swirl insert 16 and simultaneously moves axially along the expanding conical hole 17. In the nozzle mixing chamber 15 formed by the first stage 20 of a two-stage diffuser, these flows interact with their additional turbulization and crushing with the formation of a finely dispersed phase, and the second stage 21 of the diffuser with a screw heat by cutting inside it enhances the effect of atomization of the liquid. Such a fluid flow at the exit of the nozzle 15 is well disclosed due to centrifugal forces arising from the rotation of the liquid, and is finely dispersed inside the cone-shaped plume due to the turbulent flow along the axis of the nozzle 15.

In the lower part of the housing 11, coaxially to it, a cylindrical shell 22 is fixed, on which a flow divider 23 is mounted, made in the form of at least two rods 24 and 25 located obliquely to the nozzle axis, interconnected in the lower part to which they are attached a vertically located rod 26 on which a swirl is mounted, made in the form of a cone 28 with screw blades, covering the rod 26 with a gap and resting in the lower part on the stop 27, located horizontally and perpendicular to the rod 26.

Installation heat recovery equipment works as follows.

At many enterprises of the chemical, machine-building and other industries, a large amount of water is spent on cooling technological equipment, the temperature of which then reaches 35 ... 40 ° C. It is proposed to use the heat of such waste water in the supply units using recycling heat exchangers of contact and surface type. The heat recovery unit of the equipment is equipped with a frost protection system 2 and, in addition, has an increased irrigation density of the lower stage of the two-stage contact heat exchanger 1. Water from the cooling system through pipe 6 enters the heat exchanger 4, where it gives its heat to heat the water coming from the pan 3 into the heat exchanger 1 and the frost protection system 2, and then through the pipe 5 returns to the cooling system. The supply air in the heat exchanger 1 is heated, passes through a droplet eliminator 10 and then enters the air heater 9, where it is dried and heated to a predetermined temperature; the air heater is connected to the heat supply system by pipelines 7 and 8. Practice has shown that in such a unit it is possible to use the heat of water having an initial temperature of only 20 ... 25 ° C. In this case, freezing of the aggregates did not occur even at an outdoor temperature of minus 40 ° C.

Claims (1)

Equipment heat recovery installation comprising a housing, a pallet, an anti-freeze protection system, a two-stage contact heat exchanger with a nozzle and a nozzle irrigation system, a cooling system with a heat exchanger, a nozzle made of a compact thin-film corrugated film with a thickness of 0.4 ... 0.8 mm, and molded sheets nozzles are connected by glue, and the nozzle surface is alternating channels of a triangular shape, which are inclined to the axis of runoff of the coolant in a countercurrent pattern: one sheet at an angle of + 30 the other glued to it is 30 °, and the channels are made with a U-shaped corrugation along the length, characterized in that the nozzle of the irrigation system comprises a housing, a fitting and a coaxially located swirl insert with an external helical thread and an expanding conical hole inside, the inlet has a cylindrical inlet opening connected to the diffuser axisymmetrically made in the casing, and in the lower part of the casing a nozzle is arranged axisymmetrically to the casing, which is made with a two-stage and coaxial swirl insert For a diffuser, the first stage of the diffuser is a continuation of the expanding conical hole made inside the swirl insert, which is made of wear-resistant material, and the second stage of the diffuser is a continuation of its first stage, while a screw-shaped thread is made on its inner conical surface, and the conical surface is helical by cutting the second stage of the diffuser is perforated, and in the lower part of the body, coaxially to it, is mounted a cylindrical shell on which the mouth A new flow divider is made in the form of at least two rods arranged obliquely to the nozzle axis and connected to each other in the lower part, to which a vertically arranged rod is mounted, on which a swirler is mounted, made in the form of a cone with screw blades, covering the rod with a gap and leaning in the lower part on an emphasis located horizontally and perpendicular to the rod.

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