FR2665516A1 - PARTICULAR STRUCTURE FOR ACCELERATING THE REACTIVITY SPEED OF THE ZEOLITE AND METHOD OF DEPOSITING THE ZEOLITE ON THE SAME. - Google Patents

Abstract

The structure according to the invention is remarkable in that it consists of a hollow metal part (1), the outer surface of which is shaped in a regular configuration so as to have a plurality of projections (5). Application to cooling and / or heating devices, for example for vehicle air conditioners.

Description

1- The present invention relates to a structure intended to accelerate the

  speed of reactivity of the zeolite in

  cooling and / or heating devices

  forming zeolite in granules or balls.

  It applies in particular to refrigerators which require

  try very fast adsorption and desorption devices

  to produce cold, and aims to achieve

  ser a zeolite deposit on said structure.

  The zeolite must have good adhesion to the substrate.

  port or structure, high adsorption capacities and

  good heat transfer with the support.

  There are numerous prior art in the state of the art

  riorités describing methods of depositing an ad-

sorbent on a support.

  For example, patent DE-OS-25 36 006 describes a process for depositing zeolite, alumina, activated carbon, in 2 - granular or pulverized form, on a metal support which is characterized by the immersion of said support in an adequate chemical solution The dep 8 t formed is then

dried and then filtered.

  Another process for deposition of an adsorbent on a support plate is described in FR-A-2 443 485, process in

  which the sprayed adsorbent is dispersed in a solution

  alkaline and settles on the support plate after

elimination of the solvent plate.

  When circulating, under vacuum, a heat transfer fluid

  in a hollow profile intended for use in devices

  positive cooling and / or heating type

  refrigerator for example, and whose external face is re-

  clad in zeolite, covering made according to one of the

  ceded above described, the reactivity time of the zeo-

  lithe is around 40 minutes at least The zeolite,

  used in the form of granules, has a diameter

  taken between 1 and 3 mm and is held vertically in

  an aluminum or copper profile.

  The reactivity time of the zeolite is the minimum time

  to bring him heat so as to raise his time

temperature between 200 and 3000 C.

  The subject of the present invention is a particular structure.

  lière which makes it possible to improve the speed of reactivity of the zeolite thus presenting performances clearly

  It is particularly intended to be used

  in the cooling and / or cooling devices

  refrigerator-type heating for example.

  According to the invention, the structure for accelerating speed 3 -

  of reactivity of the zeolite in recovery devices

  cooling and / or heating containing zeolite in granules or in balls is characterized in that it

  consists of a hollow metal part, the surface of which

  external face is shaped in a regular configuration so as to present a plurality of projections Thus,

  the reactivity time is of the order of a minute.

  Advantageously, the configuration is constituted by 1 O of the projections arranged horizontally and vertically, in two planes, each of the projections being separated by a small and a large space of parallelepipedal shapes such as the width of the area of the upper face and

  that of the area of the underside of the small space,

  tre two projections, is of the order of 2 mm, and their lon-

  about 3 mm, and that the width of the area of

  the lower face and that of the area of the upper face

  re of the large space, between two projections, is included

  be 4 and 5 mm, and their lengths of the same order.

  Said projections are in the form of a volume

  of parallelepiped shape with a height between-

be 15 and 30 mm.

  Preferably, the width of the area of the upper face and that of the area of the underside of said volume forming a projection are of the order of 3 mm and their

  respective length is between 4 and 5 mm.

  According to another embodiment of the invention, the part

  this metallic is a rolled plate and connected to its two

ends by a weld.

  According to an important aspect of deposition of the zeolite in 4 -

  the invention, the small spaces are closed by la-

  continuous melles before the zeolite is introduced into

the great outdoors.

  Preferably, the metal part is made of aluminum.

nium or copper.

  According to another embodiment of the invention, for a good application of the zeolite on the structure, said structure is introduced into a glass tube around which is arranged a device making it possible to induce

  so-called eddy currents in the metal structure.

  This embodiment of the invention is particularly suitable for

  suitable for use in the household refrigerator

  makes its technical design very simple and its

ble manufacturing cost.

  The present invention also relates to a method of determining

  a layer of zeolite on the projections of the structure

  ture described above, characterized in that it comprises

te the following steps:

  sealing small spaces with plastic slats

  ques, introduction of zeolite in large spaces, introduction of said structure into a bath containing a solution such as that used in FR-A-2 443 485, removal of the plastic strips from the structure once out of the bath, as soon as the deposit of zeolite on the projections is carried out and sintering of the deposit of zeolite on the structure, carried out

  in an oven at a temperature of 350 ° C.

  Other features and advantages of the invention

  will result from the following description, referring

  in the accompanying drawings in which: Figure 1 is a schematic representation, seen from above, of a part of said structure, Figure la is a sectional view of a part of the

  structure along the axis I-I 'of Figure 1.

  Figure lb is a sectional view of part of the structure along the axis II-II 'of Figure 1 1 Figure 2 is a schematic sectional view along I-I'

  of a non-limiting embodiment of the structure se-

lon the invention.

  According to FIG. 1, the structure consists of a metal part 1 in which a channel 4 has been dug and on

  which have been produced series of projections 5 available

  more or less regularly according to the same long plan

  tudinal and the same plane transverse to the axis of channel 4.

  The adsorbent, here zeolite 6, adheres to the walls of the

  projections 5 adjacent to the spaces 2 The zeolite 6 presents

  te a diameter of the order of 3 mm and comes in the form

me granular.

  Before the introduction of zeolite 6 in volumes 2, we

  has in the spaces 3 plastic slats not

shown in the figures.

  According to Figure 2, there is shown an application of the structure The structure is placed in a glass tube 7

  around which is placed a medium frequency inductor

  -6- this 8 for example The structure actually consists of

  two simple juxtaposed structures with sail-

  lees 5 only on one of their sides and consequently has a configuration such that the two channels 4 are adjacent By one of the two channels 4 a the liquid or gas, hot or cold, is introduced via the

  line 11, then it is evacuated, via the tubular connection

  area 9, in the second channel 4 b, and finally rejected in the former

pipe 10.

  The zeolite 6 deposition process is carried out as follows:

  The spaces 3 are filled with plastic strips

  The zeolite 6 is then introduced into the spaces 2 Then the structure is placed in a bath containing a

  solution such as that used in FR-A-2 443 485.

  Once the zeolite has been deposited on the projection faces 5, the structure of the bath is removed and the plastic strips are removed. The structure is then introduced into an oven at a temperature of the order of 3000 ° C. to effect the sintering of zeolite 6 A thin deposit (0.1 to 0.5 mm) of zeolite 6 is then obtained on two of the faces of each projection 5, continuous deposit because the granules or grains of zeolite are also bonded to each other

  but not completely: we thus notice spaces between-

  be two grains or granules, which thus promotes the pas-

  wise gas or liquid for cooling and / or heating an enclosure The spaces 2 are also filled with zeolite (see Figures la and lb) Therefore, when using the structure, the absence of zeolite 6 on the two other faces of the projections 5 will favor the acceleration of the speed of reactivity of the zeolite 6 This speed is accelerated because the deposition of zeolite 6 carried out only on the two faces of the projections 5 has a very small thickness (between 0, 1 and 0.5 mm) thus promoting exchanges and accelerating the cooling / heating operations In addition, the arrangement of the zeolite balls or granules (6) partially glued

  only to each other will also favor exchanges

  ges: the liquid or the gas passes between the balls or the granules, thus accelerating the speed of reactivity of the zeolite 6 Said projections 5 can be compared to

heat sinks.

  According to FIG. 2, the heating of the structure arranged in a glass tube is accelerated by the inductor of

  medium frequency 8, thus promoting the speed of reaction

zeolite activity 6.

  This structure is particularly suitable for heating and / or cooling devices of the type

  refrigerator but also for vehicle air conditioning

  the. 8 - R eve N dicatio N s 1 Structure to accelerate the speed of reactivity in cooling and / or heating devices, containing zeolite in granules or beads, characterized in that it consists of a single piece metallic (1) hollow whose external surface is shaped according to a

  regular configuration so as to present a plura-

lity of projections (5).

  2 Structure according to claim 1, characterized in that the configuration consists of projections (5) arranged horizontally and vertically, in two planes, each of the projections being separated by a small (3) and a large (2) form spaces parallelepipedic such that the width of the area of the upper face and that of the area of the underside of the small space (3), between two projections, is of the order of 2 mm, and their lengths of the order 3 mm, and that the width of the area of the lower face and that of the area of the upper face of the large space (2), between two projections, is between

  4 and 5 mm, and their lengths of the same order.

  3 Structure according to claim 1 or 2, characterized in that the projections (5) are in the form of a volume of parallelepiped shape with a height

between 15 and 30 mm.

  4 Structure according to claim 3, characterized in that the width of the area of the upper face and that of the area of the underside of said volume form a projection (5) of the order of 3 mm and in that their length

  respective is between 4 and 5 mm.

  9 - Structure according to claim 1, characterized in that

  that the metal part (1) is a rolled plate and

  linked at both ends by a weld.

  6 Structure according to claim 1 or 2, characterized

  in that the small spaces (3) are closed by la-

  continuous melles before the zeolite is introduced (6)

in large spaces (2).

  7 Structure according to any one of claims 1

  to 6, characterized in that the metal part (1) is made of aluminum.

  8 Structure according to any one of claims 1

  1.5 to 6, characterized in that the metal part (1) is made of copper.

  9 Structure according to any one of claims

  previous, characterized in that it is introduced into a glass tube (7) around which is arranged a device (8) for inducing so-called eddy currents

in the structure.

  Method of depositing a layer of zeolite on the

  protrusions of the structure described in claims 1

  to 10, characterized in that it comprises the following steps:

your:

  sealing small spaces (3) with plastic strips

  ticks, introduction of zeolite (6) in small spaces

(2),

  introduction of said structure into a bath containing a solution such as that used in FR-A-2 443 485, - removal of the plastic strips from the structure once out of the bath, as soon as the deposit of zeolite on the projections (5) is realized and

  sintering of the zeolite deposit (6) on the structure,

  read in an oven at a temperature of 350 ° C.