FR2779219A1 - Industrial thermal energy recovery installation - Google Patents

Abstract

The industrial installation comprises a unit (1) comprising a water cooling circuit (5) and a cooling water cooling tower (3). It also includes a unit for the vaporization of liquid nitrogen comprising a water pool (2) containing a thermal vaporization exchanger (10), and a reheating circuit (18,19,4B,20) for the pool water and its return to the pool after reheating. A pre-cooling circuit (14,4A,15) for the cooling water leaving the industrial unit sends it to the cooling tower. A heat recovery exchanger (4) exchanges heat between the reheating circuit and the pre-cooling circuit.

Description

The present invention relates to an industrial installation of the type

  comprising an industrial unit comprising a cooling water circuit, and a cooling tower for the cooling water which leaves the industrial unit. It applies for example to steel units. Some industrial units require a cooling water circuit. This water must then be cooled, either to be discharged or to be

recycled to the unit.

  The invention aims to enhance energy

  contained in the cooling water.

  To this end, it relates to an industrial installation of the aforementioned type, characterized in that it further comprises: - an apparatus for vaporizing at least one cryogenic liquid, this apparatus comprising a water pool which contains a heat exchanger vaporization, and a circuit for heating the pool water and returning the heated water to the pool; - a circuit for precooling the cooling water which leaves the industrial unit and sending the precooled water to the cooling tower; and - a recovery heat exchanger which brings the heating circuit into heat exchange relation and

the precooling circuit.

  The installation according to the invention may include one or more of the following characteristics, taken individually or in all their technically possible combinations: - the precooling circuit conveys the entire flow of cooling water leaving the industrial unit; - the precooling circuit conveys a fraction of the cooling water flow leaving the industrial unit, the rest of this flow being sent directly to the cooling tower; - the swimming pool is equipped with additional heating elements and / or an additional water supply and / or an overflow; - the installation includes a circuit for returning to the industrial unit the cooled water from the cooling tower; - the cryogenic liquid is liquid oxygen or liquid nitrogen; - The swimming pool contains several vaporization heat exchangers adapted to deliver gas flows from one or more fluids at different flow rates and / or under pressures; - the recovery heat exchanger is a brazed plate exchanger; - the gas from the vaporization is, at least in part, sent to the industrial unit; and

  - the industrial unit is a steel unit.

  An exemplary embodiment of the invention will now be described with reference to the accompanying drawing, the single figure of which schematically represents an installation.

  industrial according to the invention.

  The installation shown in the drawing essentially comprises an industrial unit 1, for example a steelworks, a swimming pool 2 for vaporizing a cryogenic fluid, which is liquid nitrogen in this example, a water cooling tower 3, and a heat exchanger

  heat 4 of the indirect type with brazed aluminum plates.

  As is well known, such a heat exchanger consists of a large number of rectangular plates

  parallels kept spaced by spacer waves.

  These plates define between them numerous fluid circulation passages of generally flat shape, which are closed on their periphery by bars. The bars are interrupted so as to define for each passage an inlet window and an outlet window for the fluid in question, and all the corresponding windows are aligned and capped by an inlet / outlet box of

general semi-cylindrical shape.

  Unit 1 has an internal cooling water circuit 5. This water comes from the tank 6 of the cooling tower via pipes 7 equipped with a pump

  8 and fitted at their entrance into the tank 6 with a strainer 9.

  Pool 2 contains a nitrogen vaporization coil 10 supplied with liquid nitrogen via a line 11 and delivering via a line 12 nitrogen gas at around +15 C. At least part of this nitrogen gas is sent to the unit 1 via line 13 to be there

consumed.

  The relatively hot water, for example at about C, which leaves the circuit 5 is sent via a pipe 14 to the hot end of the exchanger 4, which it crosses to its cold end in passages 4A of the exchanger from where she

comes out around 40 C.

  From there, the water is sent via a pipe 15 to spraying ramps 16 provided at the head of the cooling tower. The water continues to cool down to around ambient temperature, descending along this tower to tank 6, thanks to an air flow

  atmospheric supplied by fans 17.

  Simultaneously, water is taken from the bottom of the swimming pool 2 via a pipe 18 fitted with a pump 19, and is introduced at the cold end of the exchanger 4. This water heats up from the cold end to the hot end of the exchanger, in passages 4B thereof, by indirect heat exchange with the cooling water from unit 1 supplied via line 14. After it leaves the hot end of the exchanger, the water thus heated is returned to pool 2 via

a pipe 20.

  As shown diagrammatically, the swimming pool 2 also includes a cover 21 through which emergency electrical resistances 22 plunge into the swimming pool, a supply of make-up water 23 controlled by a

float 24, and an overflow 25.

  The installation also includes a set of valves and control and regulation means, known per se, which make it possible to ensure the proper functioning of the

water circulation circuits.

  As can be understood, thanks to the heat exchange which occurs in 4, the heat energy contained in the cooling water is recovered, to the extent necessary, to supply the water in the pool 2 with the necessary calories. to the vaporization of nitrogen in the coil 10. Given the high flow rate of this cooling water, it is possible to obtain vaporization of large nitrogen flows without operating the resistors 22, which are only used '' in the event of a malfunction in the water circuits. Substantial energy savings can thus be obtained for vaporization

nitrogen.

  In addition, the cooling water from the unit 1 reaches the already precooled cooling tower 3, so that a reduced amount of heat must be removed from this water to bring it back to the vicinity of ambient temperature. Significant energy savings are therefore also obtained for driving the fans 17. As a variant, the water collected in the tank 6 can be discharged and the unit 1 be cooled by a source.

  free cold water such as a river.

  Alternatively also, as indicated in phantom in 114 in the drawing, only a fraction of the flow of cooling water from the unit 1 can be sent in line 14, the rest of this flow then being directly

  sent to the ramps 16 of the cooling tower.

  Pool 2, or several similar pools mounted in parallel, may or may contain several vaporization exchangers such as the coil 10, in order to supply several gas flows, namely several flows of the same gas at flow rates and / or under different pressures, and / or different gas flows, for example oxygen and nitrogen.

Claims (7)

RESELL I CATIONS   1 - Industrial installation, of the type comprising an industrial unit (1) comprising a circuit (5) of cooling water, and a tower (3) for cooling the cooling water which leaves the industrial unit, characterized in what it further comprises: - an apparatus for vaporizing at least one cryogenic liquid, this apparatus comprising a water pool (2) which contains a vaporization heat exchanger (10), and a circuit (18, 19, 4B, 20) for heating the pool water and returning the heated water to the pool; - a circuit (14, 4A, 15) for precooling cooling water leaving the industrial unit (1) and for sending the precooled water to the cooling tower (3); and - a recovery heat exchanger (4) which places the heating circuit (18, 19, 4B, 20) and the heating circuit in heat exchange relationship. precooling (14, 4A, 15).   2 - Industrial installation according to claim 1, characterized in that the precooling circuit (14, 4A, 15) conveys the entire flow of cooling water leaving the unit industrial (1).   3 - Industrial installation according to claim 1, characterized in that the precooling circuit (14, 4A, 15) conveys a fraction of the flow of cooling water leaving the industrial unit (1), the rest of this flow being sent   directly to the cooling tower (3).   4 - Industrial installation according to one   any one of claims 1 to 3, characterized in that   the swimming pool (2) is equipped with supplementary heating elements (22) and / or a supplementary water supply (23) and / or an overflow (25).   - Industrial installation according to one   any one of claims 1 to 4, characterized in that   that it includes a circuit (7, 8) for returning to the industrial unit (1) the cooled water from the tower cooling (3).   6 - Industrial installation according to one   any one of claims 1 to 5, characterized in that   the cryogenic liquid is liquid oxygen or liquid nitrogen.   7 - Industrial installation according to one   any one of claims 1 to 6, characterized in that   the swimming pool (2) contains several vaporization heat exchangers adapted to deliver gas flows from one or more fluids at different flow rates and / or under different pressures. 8 - Industrial installation according to one   any one of claims 1 to 6, characterized in that   the recovery heat exchanger (4) is an exchanger with brazed plates.   9 - Industrial installation according to one   any one of claims 1 to 8, characterized in that   the vaporizing gas is, at least in part,   sent to the industrial unit (1).   - Industrial installation according to one   any one of claims 1 to 9, characterized in that   the industrial unit (1) is a steel unit.