DE102015215252A1 - Distribution device and motor vehicle - Google Patents

Abstract

The invention relates to a distributor device (22) for a gas / liquid mixture (20), in particular a cooling system (12) of a motor vehicle (2), having at least two output lines (26, 28) into which an inlet line (38) having a constriction (38) 24) opens. The constriction (38) is spaced from the junction (30). The invention further relates to a motor vehicle (2) having a cooling system (12) which has a distributor device (22) and the use of a distributor device (22).

Description

The invention relates to a distributor device for a gas / liquid mixture. The distribution device is in particular part of a cooling system of a motor vehicle. The invention further relates to a motor vehicle with a distributor and the use of a distributor.

For driving motor vehicles electric motors are increasingly used. For example, these drive directly individual wheels of the motor vehicle, for example as so-called wheel hub motors. in one variant, only electric motors are used for driving the motor vehicle. An alternative to this is the use of a so-called hybrid system, in which, in addition to the electric motors, an internal combustion engine is available for driving the wheels. The electric motors have a supporting effect in this case, primarily during acceleration. During deceleration of the motor vehicle, the electric motors are operated by means of suitable control as a generator, so that the kinetic energy of the motor vehicle is converted into electrical energy, which is available at a later time for driving the motor vehicle. As a result, the efficiency of the motor vehicle is increased.

For the provision of electrical energy for the electric motors so-called high-voltage batteries are used as energy storage, which are based for example on a metal hydride technology or a lithium-ion technology. Each high-voltage battery comprises a number of cells, each formed by a single battery, and connected together appropriately. The electrical voltage provided by the energy store is up to 400 volts. In particular, when charging the energy storage is heated. This heating can lead to damage to the energy storage and even to a thermal misconduct, ie a burn of individual energy cells of the energy storage. As a result, cooling of the energy storage is required.

For this purpose, evaporators are usually used, in which a gas / liquid mixture is passed through a piping system. With an expansion and thus a pressure reduction, the temperature decreases and the environment is deprived of thermal energy. An alternative to this is that the liquid of the gas / liquid mixture is completely vaporized, which also leads to a reduction in the thermal energy of the components, which are in thermal contact with the evaporator. The thus enriched with thermal energy gas / liquid mixture is fed to a condenser and a compressor, and compressed there again to an elevated pressure. As a result, thermal energy is released to the environment of the capacitor. Usually, the region of the thermal energy absorption in the region of the energy storage of the motor vehicle is arranged, whereas the region of the energy delivery is in thermal contact with an environment of the motor vehicle, so that the thermal energy is released into the environment of the motor vehicle.

For reasons of cost, the cooling system usually comprises only a single section in which the pressure increases and thermal energy is released into the environment. However, in order to ensure a comparatively high cooling capacity, all individual cells of the energy storage device, usually more than 100 units, are each supplied with an associated line of the evaporator. Here, the individual lines are fluidly coupled together so that each individual energy cell is cooled to the same extent. As a result, a distribution of guided in a main gas / liquid mixture to the individual connected in parallel and leading to the cells lines is required, which is done by means of a distributor.

In order to achieve a comparatively efficient use of space, the individual lines of the cooling system are bent and consequently have bends (curves). These bends act in the manner of a centrifugal separator, so that on the outside walls of the wall, the liquid precipitates, whereas on the inside there is an accumulation of the gas. If this line opens into a tee, gas is thus predominantly introduced into one of the outgoing lines, whereas in the remaining one predominantly a liquid is introduced. As a result, the homogeneity of the refrigerant is no longer present, so that individual cells of the energy storage comparatively efficient, the others are cooled only to a reduced extent.

The invention has for its object to provide a particularly suitable distribution device and a particularly suitable motor vehicle with a cooling system, in particular, a division of the gas / liquid mixture is relatively homogeneous.

With regard to the distribution device, this object is achieved by the features of claim 1 and in terms of the motor vehicle by the features of claim 9 according to the invention. Advantageous developments and refinements are the subject of the dependent claims.

The distribution device is suitable to transport a gas / liquid mixture and to to distribute. In particular, the distribution device is provided and arranged to transport the gas / liquid mixture. Here, the gas / liquid mixture of the distributor is supplied upstream by means of a supply, and discharged downstream by means of a discharge, in particular, a greater number of discharges is present as at feeders. In particular, the distributor device has only a single feed and at least two outlets. In operation, by heating the gas / liquid mixture or by evaporating the liquid of the gas / liquid mixture, a heat reservoir, such as the environment of part of the cooling system, is deprived of thermal energy. Preferably, the distribution device is part of a condenser or an evaporator, or to the distribution device, an evaporator or a condenser is fluidly coupled.

In particular, the distribution device is part of a motor vehicle, for example a cooling system of a motor vehicle. By means of the cooling system, preferably high-voltage batteries of the motor vehicle are cooled during operation. The motor vehicle is in particular an electric or a hybrid vehicle which has at least one electric motor and an internal combustion engine which serve for propulsion. The high-voltage battery expediently has an electrical voltage greater than 100 volts, 200 volts or 300 volts and, for example, less than 500 volts, 600 volts or 700 volts. In particular, the electrical voltage is equal to 400 volts. The gas / liquid mixture is expediently a mixture of air and water. In other words, ambient air is used as gas, and water as liquid. In this way, a risk of persons due to any toxic components is excluded in a leakage of the distribution device. In an alternative to this, ammonia, carbon dioxide or a hydrocarbon is used as the refrigerant / coolant, each of which is mixed with air, for example. Preferably, the gas / liquid mixture is prepared by means of a refrigerant, in particular by means of tetrafluoroethane, such as 1,1,1,2-tetrafluoroethane (R-134a), tetrafluoropropene, such as 2,3,3,3-tetrafluoropropene (R1234yf), and preferably consists thereof.

The distribution device comprises an input line which forms the supply to the distribution device at least in sections. In other words, in operation, the gas / liquid mixture is supplied through the input line. The distribution device further comprises two output lines, each forming at least in sections one of the discharges of the distribution device. The input line opens into the two output lines, so that during operation, the gas / liquid mixture supplied by means of the input line is discharged by means of the two output lines and consequently distributed to the two output lines.

The input line has a constriction which is spaced from the entrance of the input line into the output lines. In other words, the cross-section of the input conduit between the constriction and the confluence is widened compared to the cross-section in the region of the constriction. Consequently, the input line has a first cross-sectional area upstream of the constriction, a second cross-sectional area in the region of the constriction and a third cross-sectional area downstream of the constriction. Both the first and the third cross-sectional area is larger than the second cross-sectional area. Downstream of the constriction refers to the area of the inlet duct which is located between the confluence and the constriction, whereas upstream of the constriction designates the area of the inlet conduit which is located on the constricting side of the confluence.

As a result, the supplied gas / liquid mixture first passes through a portion of the input conduit prior to necking and is subsequently directed therethrough through the constriction. Due to the cross-sectional area reduction, the mixture is accelerated, thus resulting in a reduction of the static pressure. Thus, the gas is mixed with the liquid, which is why the mixture after passage of the constriction is substantially homogeneous. After passage of the constriction is due to the cross-sectional widening again a deceleration of the mixture, and the static pressure increases. Consequently, a pressure loss is reduced when introduced into the output lines, so that a cooling capacity is increased, provided that the distribution device is part of a cooling system.

In summary, the constriction is a cross-sectional reduction of the input line, which, however, is local. The cross-sectional reduction is spaced from the confluence, thus having an enlarged cross-section compared to the cross-sectional reduction. Also upstream of the constriction, ie on the opposite side of the constriction of the constriction, the cross section is greater than in the region of the cross-sectional reduction.

For example, the distribution device comprises two, three or more output lines, into which the input line opens. Preferably, the cross section of the input line is square, oval or preferably round. In particular, the input line is rotationally symmetrical. For example, the Constriction rotationally symmetric, which improves the homogenization of the gas / liquid mixture. Conveniently, the input line is composed of a number of pipe sections, which are in particular formed on each other. Conveniently, such a pipe section forms a portion of the input line upstream of the constriction and another piece of pipe a portion of the input line downstream of the constriction. These are in particular arranged concentrically to each other, but axially spaced from each other. Conveniently, the constriction is realized by means of a pipe section, which has a reduced compared to the two pipe sections inner diameter, and which is also arranged concentrically to the two pipe sections, axially between them.

For example, the transition between the respective pipe sections and the pipe section is funnel-shaped or the two pipe sections with the enlarged diameter have a bottom, is connected to the butt of the constriction forming pipe section, in particular is formed. In this way, there is a comparatively strong influence on the movement of the gas / liquid mixture, which consequently leads to a comparatively pronounced mixing of the gas and the liquid and consequently a comparatively high homogeneity of the mixture. In a further embodiment of the invention, the input line is designed waisted in the region of the constriction, in particular by means of an inwardly directed curvature, which is preferably rotationally symmetrical. In this way, a flow resistance is reduced and consequently an efficiency is increased. For example, the constriction is created by means of rotary swaging, hammering or another manufacturing process.

For example, the cross-sectional area upstream of the input line is equal to the cross-sectional area downstream of the input line. Thus, the flow rate of the mixture upstream and downstream of the throat is substantially equal. In particular, the cross section upstream and downstream of the constriction is the same. In this way it is possible to use for the input line, a standardized pipe or the like, in which after the manufacture of the tube, the constriction is introduced. In this way, manufacturing costs are further reduced.

Conveniently, the smallest cross-sectional area of the constriction is between 10% and 90% of the cross-sectional area of the input conduit which is upstream or downstream of the constriction, that is, the cross-sectional area upstream or downstream of the constriction. For example, the smallest cross-sectional area of the constriction is between 20% and 80%, 30% and 75%, more preferably between 50% and 70%, and conveniently equal to 60% of the cross-sectional area of the input conduit upstream or downstream of the constriction. In this way, on the one hand, a comparatively large volume throughput through the constriction and, on the other hand, a comparatively large homogenization of the gas / liquid mixture are ensured.

For example, the input line has an inner diameter between 4 mm and 12 mm, in particular between 6 mm and 10 mm and preferably equal to 8 mm. In this way, the space requirement of the distribution device is comparatively low. For example, the input line is made of a plastic or preferably of a metal, such as an aluminum, so an aluminum alloy or pure aluminum. More preferably, a 3000 aluminum alloy is used, which consequently comprises manganese, resulting in a comparatively hard distributor. Conveniently, the distance between the constriction and the mouth of the input line in the two output lines between 1 mm and 20 mm, for example between 5 mm and 15 mm and in particular equal to 10 mm. In this way, segregation of the gas / liquid mixture after passage of the constriction is substantially precluded, and a comparatively homogeneous mixture flows into the two exit conduits, so that the volume fraction of the gas and liquid passed into each of the two exit conduits is substantially equal ,

Preferably, the input line and the output lines are connected at the free end. In other words, the input line terminates at the confluence with the two output lines, and the two output lines begin at the junction. As a result, in operation, the same pressure prevails at the free ends of the two output lines connected to the input line, and therefore a division of the gas / liquid mixture between the two output lines is improved. Also, a deposition of components of the gas / liquid mixture at a freiendseitigen connection between the three lines is substantially excluded. Conveniently, the input line is integrally formed on the two output lines. In other words, the input line is integral with the two output lines. In this way, it is possible to minimize flow resistance, which increases the efficiency, and a production is simplified. Conveniently, the composite of the three lines, in particular the complete distributor, made of a metal such as aluminum or an aluminum alloy, such as. As an aluminum 3000 alloy.

For example, the input line ends flush with the inner diameter of the two output lines. In other words, the input line does not protrude into either of the two output lines, and also the two output lines do not protrude into the input line. As a result, flow resistance is reduced and efficiency is increased. Suitably, the inner diameter of the two exit conduits is the same, and in particular equal to the inner diameter of the entry conduit, so that the flow rate of the mixture in the two exit conduits equals half the flow rate of the mixture in the entry conduit. In an alternative to this, the cross-sectional area of the two exit conduits is equal to half the cross-sectional area of the entrance conduit, except for the constriction, and the inner diameter is thus adapted to such a cross-section. Thus, the flow rate of the gas / liquid mixture within the distributor is substantially constant except in the area of constriction.

For example, the two output lines are antiparallel to each other. In other words, the two output lines are arranged on a straight line and connected on the free end side. In this way, the gas / liquid mixture is transported away after passage of the confluence in the opposite direction. Alternatively or in a particularly preferred combination for this purpose, the input line is perpendicular to at least one of the output lines, thus consequently to both, provided that they are arranged antiparallel to each other. At least the angle formed between one of the two output lines and the input line in the region of the junction is 90 °. Consequently, the distribution device is manufactured in the manner of a T-piece. For example, an extension is connected to one of the two output lines, particularly preferably to both output lines, in particular formed, but having a different orientation, for example, the extension includes a bend, so that the gas / liquid mixture can be transported by means of the distributor to any spatial positions.

For example, the input line comprises a bend upstream of the constriction. In other words, in operation, the direction of the gas / liquid mixture before bending does not correspond to the direction of the gas / liquid mixture after bending. Upon passage of the bend, due to the inertia, the liquid is conveyed to the bend-outward portion of the bend, whereas the comparatively light gas remains in the area of the bend-inward wall. As a result, by means of the bending, a separation of the gas / liquid mixture takes place in the manner of a centrifugal separator. The gas / liquid mixture segregated in this way passes through the constriction, where once again a homogenization of the gas / liquid mixture takes place. Consequently, when introduced into the two exit lines, the gas / liquid mixture has a comparatively high degree of homogeneity although this has passed the bend. Due to the introduction of the bend, it is possible by means of the cooling system to cool components which are arranged in any geometric arrangement, provided that the distribution device is part of a cooling system.

Particularly preferably, the input line between the junction and the constriction is rectilinear. In other words, the input line between the junction and the constriction has no bend. Consequently, the homogeneity of the gas / liquid mixture after passage of the constriction is not further influenced by the geometry of the input line.

The motor vehicle has a cooling system, which is for example provided and expediently arranged to cool an energy store of the motor vehicle, such as a high-voltage battery, which is based for example on a nickel-cadmium or lithium-ion technology. In particular, the high-voltage battery comprises a number of individual energy cells (cells) which are cooled by means of the cooling system. The cooling system (refrigeration system) has a distribution device for a gas / liquid mixture (refrigerant / coolant), which is in particular a refrigerant, such. For example, tetrafluoroethane or tetrafluoropropene. By means of the distributor, a condenser or an evaporator with the gas / liquid mixture is applied. By means of the evaporator part of the liquid of the gas / liquid mixture is evaporated, so that the environment of the cooling system in this area heat is removed. The evaporator is located in the region of the energy store, and is in particular thermally coupled with it. The distribution device comprises two output lines and an input line which has a constriction, ie a local reduction in cross section, upstream and downstream of the constriction of which the cross section of the input line is greater than in the region of the constriction. The input line opens into the two output lines, wherein the constriction is spaced from the junction in the two output lines.

A distributor having two output conduits into which a necked inlet conduit terminates, the throat being spaced from the confluence, is used to transport a gas / liquid mixture, the gas / liquid mixture passing first through the inlet conduit and thence into the two Output lines is transported. In particular, such a distribution device is used within a cooling system (refrigeration system) of a motor vehicle.

Embodiments of the invention will be explained in more detail with reference to a drawing. Show:

1 schematically simplifies a motor vehicle with a cooling system,

2 in a sectional view a distribution device of the cooling system, and

3 according to 2 a further embodiment of the distribution device.

Corresponding parts are provided in all figures with the same reference numerals.

In 1 schematically simplified is a motor vehicle 2 represented, which is designed as an electric vehicle. For this purpose, the motor vehicle includes 2 Electric motors designed as wheel hubs 4 , one of which is one of the four wheels 6 is assigned, of which only two are shown. Each of the electric motors 4 is by means of a power line 8th and a converter, not shown, with an energy storage 10 electrically contacted. The energy storage 10 has a number of energy cells, not shown, which are made of lithium. At a deceleration of the motor vehicle 2 is by means of operated as a generator electric motors 4 mechanical rotation energy wheels 6 converted into electrical energy that enters the energy store 10 is fed. As a result, the energy storage 10 heated. Even with an energy withdrawal is a heating of the energy storage 10 due to the internal resistance of the energy cells.

To prevent excessive heating of the energy store 10 to prevent, the motor vehicle has 2 a cooling system 12 with a compressor 13 , a capacitor 14 as well as an evaporator 16 on, by means of cooling pipes 18 fluidly coupled. The evaporator 16 is in thermal contact with the energy storage 10 , and the capacitor 14 is during operation of the motor vehicle 2 acted upon by driving air. When operating the cooling system 12 is by means of one of the cooling line 18 one inside the cooling system 12 located gas / liquid mixture 20 to the evaporator 16 directed. By means of the evaporator 16 becomes a part of the liquid content of the gas / liquid mixture 20 evaporated, which by means of a reduction in pressure of the gas / liquid mixture 20 he follows. Consequently, the energy storage 10 withdrawn thermal energy. By means of another of the cooling lines 18 becomes the gas / liquid mixture 20 having a reduced proportion of liquid, but an increased proportion of gas, the compressor 13 where it is compressed again to the original pressure, resulting in an increase in the temperature of the gas / liquid mixture 20 leads. Following this is the gas / liquid mixture 20 the capacitor 14 fed. There, the liquid of the gas / liquid mixture 20 condensed, with thermal energy to the airstream, and thus in the environment of the motor vehicle 2 is delivered. The thus obtained in turn gas / liquid mixture 20 gets back to the evaporator 16 by means of one of the cooling lines 18 fed.

In 2 is a distributor 22 of the cooling system 12 represented by means of which the gas / liquid mixture 20 inside the evaporator 16 is transported to the individual battery cells. The distribution device shown in a sectional view 22 has an input line 24 and a first output line 26 and a second output line 28 on, each having a circular cross-section. The two output lines 26 . 28 are formed on the freiendseitig each other and arranged in anti-parallel to each other. In the area of the connection of the two output lines 26 . 28 opens the entrance line 24 in the two output lines 26 . 28 under formation of a junction 30 one. In this area, the input line runs 24 perpendicular to the two output lines 26 . 28 so by means of the three wires 24 . 26 . 28 a tee 32 is formed. Also, the input line ends 24 in the area of the confluence 30 , so that they also freiendseitig with the two output lines 26 . 28 connected is. The input line 24 and the two output lines 26 . 28 are made in one piece from an aluminum alloy 3000.

Furthermore, the input line ends 24 in the area of the confluence 30 flush with the inside diameter 34 of the two, the same inner diameter 34 having output lines 26 . 28 , In other words, the input line protrudes 24 not in the two output lines 26 . 28 into it. Also the two output lines 26 . 28 do not protrude into the input line 24 , The inner diameter 34 the two output lines 26 . 28 is 8 mm, and is equal to an inner diameter 36 the input line 24 These except in the area of a constriction 38 having. In other words, the input line 24 except in the area of constriction 38 the constant inner diameter 36 on, which is also 8 mm. Consequently, the cross-section is by means of the inner diameter 36 is determined, and each of which is circular, except in the area of constriction 38 constant.

The constriction 38 is a reduction of the cross section and the junction 30 spaced. In other words, by means of the constriction 38 the inner diameter 36 reduced, wherein the reduction of the cross-sectional area created in this way substantially 60% of the cross-sectional area of the means of the inner diameter 36 is formed cross-sectional area. The cross-sectional and consequently inner diameter reduction in the area of the constriction 38 is continuous, so the constriction 38 is essentially formed by means of a sidecut. In other words, the constriction is 38 by means of a curvature of the input line 24 provided to the inside, which is rotationally symmetrical.

With the exception of a bend 40 is the input line 24 straight, whereby by means of the bend 40 essentially a 90 ° curve is realized. Consequently, also between the confluence 30 and the constriction 38 the input line 24 straight. Between the junction 30 and the constriction 38 is a distance 42 formed by 10 mm.

In operation, by the one feeder 44 forming end of the input line 24 that from the two output lines 26 . 28 is spaced, the gas / liquid mixture 20 initiated and by means of bending 40 diverted. As a result, there is a segregation of the gas / liquid mixture 20 due to the increased inertia of the liquid instead. The thus inhomogeneous mixture 20 is constricted by the constriction 38 where, due to the reduced inside diameter, the liquid is again mixed with the gas, and these two components are accelerated. After passage of the constriction 38 becomes the mixture 20 braked again, as the input line 24 again the original inner diameter 36 why the static pressure increases again. The thus homogenized mixture again 20 is by means of the confluence 30 both in the first and in the second output line 26 . 28 initiated, the composition of the in each of the two output lines 26 . 28 directed portion of the mixture 20 due to the homogenization by means of the constriction 38 is equal to. By means of the first output line 26 becomes the mixture 20 a first discharge 46 and by the second output line 28 a second discharge 48 fed. The two discharges 46 . 48 are arranged on a straight line, being substantially midway between the two discharges 46 . 48 the junction 30 located.

In 3 is another embodiment of the distribution device 22 shown. The two output lines 26 . 28 as well as the confluence 30 is left unchanged, whereas the input line 24 is changed. By means of the bend 40 namely, a curve is formed around a changed angle. Also, the constriction 38 changed. Compared to the in 2 The embodiment of the reduction in cross-section, which has a curved wall and is shown by means of a substantially continuous change in the inner diameter, has the in FIG 3 variant shown a kink 50 on, to which an intermediate piece 52 is formed. The intermediate piece 52 is also a straight tube, but with a reduced inside diameter. In other words, by means of the bend 50 and the intermediate piece 52 the input line 24 funnel-shaped. Downstream of the intermediate piece 52 is the constriction 38 by another kink 54 again to the original inner diameter 36 the input line 24 above. Consequently, the input line 24 in the area of constriction 38 comparatively abrupt changes in the inner diameter, resulting in comparatively large turbulence of the gas with the liquid and thus a homogenization of the gas / liquid mixture 20 elevated.

The invention is not limited to the embodiments described above. Rather, other variants of the invention can be derived therefrom by the person skilled in the art without departing from the subject matter of the invention. In particular, all the individual features described in connection with the individual embodiments are also combinable with one another in other ways, without departing from the subject matter of the invention.

LIST OF REFERENCE NUMBERS

2

motor vehicle

4

electric motor

6

wheel

8th

power line

10

energy storage

12

cooling system

13

compressor

14

capacitor

16

Evaporator

18

cooling line

20

Gas / liquid mixture

22

distributor

24

input line

26

first output line

28

second output line

30

junction

32

Tee

34

Inner diameter output line

36

Inner diameter input line

38

constriction

40

bend

42

distance

44

feed

46

first discharge

48

second discharge

50

kink

52

connecting piece

54

another kink

Claims (10)

Distribution device ( 22 ) for a gas / liquid mixture ( 20 ), in particular a cooling system ( 12 ) of a motor vehicle ( 2 ), with at least two output lines ( 26 . 28 ), in which a constriction ( 38 ) having input line ( 24 ), the constriction ( 38 ) from the confluence ( 30 ) is spaced. Distribution device ( 22 ) according to claim 1, characterized in that the cross-sectional area, in particular the cross-section, of the input line ( 24 ) upstream and downstream of the constriction ( 38 ) is equal to. Distribution device ( 22 ) according to claim 1 or 2, characterized in that the smallest cross-sectional area of the constriction ( 38 ) between 50% and 70%, in particular 60% of the cross-sectional area of the input line ( 24 ) upstream or downstream of the constriction ( 38 ) is. Distribution device ( 22 ) according to one of claims 1 to 3, characterized in that the input line ( 24 ) upstream of the constriction ( 38 ) an inner diameter ( 36 ) between 4 mm and 12 mm, in particular 8 mm, and / or that the distance ( 42 ) between the constriction ( 38 ) and the junction ( 30 ) is between 1 mm and 20 mm. Distribution device ( 22 ) according to one of claims 1 to 4, characterized in that the input line ( 24 ) and the at least two output lines ( 26 . 28 ) Freiendeiteitig connected, in particular to each other are formed, wherein the input line ( 24 ) in particular flush with the inner diameter ( 34 ) of the output lines ( 26 . 28 ) ends. Distribution device ( 22 ) according to claim 5, characterized in that the output lines ( 26 . 28 ) are antiparallel to each other, and / or that the input line ( 24 ) perpendicular to at least one of the output lines ( 26 . 28 ). Distribution device ( 22 ) according to one of claims 1 to 6, characterized in that the input line ( 24 ) upstream of the constriction ( 38 ) a bend ( 40 ) having. Distribution device ( 22 ) according to one of claims 1 to 7, characterized in that the input line ( 24 ) between the constriction ( 38 ) and the junction ( 30 ) is straight. Motor vehicle ( 2 ) with a cooling system ( 12 ), which is a distribution device ( 22 ) according to one of claims 1 to 8. Use of a distribution device ( 22 ) according to one of claims 1 to 8 for transporting a gas / liquid mixture ( 20 ), in particular within a cooling system ( 12 ) of a motor vehicle ( 2 ).

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