KR101574873B1 - Heat exchanger having an improved anti-corrosion function - Google Patents

Abstract

The heat exchanger having the improved corrosion prevention function according to the present invention includes a cool sink block 13, two temperature control modules 11 installed on opposite sides of the cool sink block 13, 11, the cool sink block 13 and the first and second hot-swivel blocks 12a, 12b are provided with a first hot-swivel block 12a and a second hot-swivel block 12b, Each of the cool sink block 13 and the first and second hot-mix blocks 12a and 12b is formed with an outflow inlet 14 through which the temperature control fluid flowing therein flows, 14 are each fastened in an assembled manner to the connectors 18 formed of an insulating material. The cool sink block 13 and the first and second hot-lock blocks 12a and 12b sequentially pass through the first hot-lock block 12a, the cool-sink block 13, and the second hot- And are coupled to each other by insulating bolts 15 formed of a material. Further, a ground wire 16 is provided in the cool sink block 13. According to this, leakage of leakage current into each heat exchange block, especially the hot-mix block, of the heat exchanger is blocked, thereby suppressing the generation of a potential difference, thereby preventing corrosion.

Description

{HEAT EXCHANGER HAVING AN IMPROVED ANTI-CORROSION FUNCTION}

The present invention relates to a heat exchanger, and more particularly, to a heat exchanger including a heat sink module and a cool sink block disposed on a side of a cooling module to which a heater is applied, and a hot- The present invention relates to an improved heat exchanger having improved corrosion prevention function.

A thermoelectric element is an electronic device using a Peltier effect. It has a form in which P-type and N-type thermoelectric semiconductors are connected. When a DC power source is connected, an endothermic phenomenon occurs at one end and a heat phenomenon occurs at the other end . A thermoelectric module composed of a plurality of such thermoelectric elements is advantageous in terms of high reliability due to a solid structure, semi-permanent life span, precision and ease of temperature control, so that the semiconductor process, cooling of a computer CPU, Sheets and the like. Particularly, in a semiconductor process, a water-cooled heat exchanger using a thermoelectric module is generally used.

1 is a configuration diagram of a water-cooled heat exchanger 10 using a thermoelectric module used in a conventional semiconductor process. The water-cooled heat exchanger 10 using a thermoelectric module includes a thermoelectric module 1 and a heat exchange block 2, 3 arranged to contact one end and the other end of the thermoelectric module 1. The heat exchange block in contact with one end of the thermoelectric module 2 where the endothermic phenomenon occurs is cooled by the endothermic reaction of the thermoelectric module as a cool sink block 3 and the heat generated in the thermoelectric module 1 The heat exchange block in contact with the other end of the heat sink block 2 is heated by a heat reaction of the thermoelectric module as a hot sink block 2.

The water-cooled heat exchanger 10 using the thermoelectric module illustrated in FIG. 1 is composed of a pair of hot-mix blocks 2, a cool-sink block 3, and two thermoelectric modules 1 disposed therebetween, So as to increase the cooling heat quantity of the sink block 3. However, it may include a plurality of heat conduction blocks and thermoelectric modules depending on the required degree of cooling and usage.

The coolant block 3 is supplied with coolant through the inflow / outflow port 3a, circulates the coolant, circulates the coolant, and flows out to the object to be cooled. Process cooling water (PCW) flows into the hot-mix block 2 through the inflow / outflow port 2a to cool the hot-mix block 2 heated by the thermoelectric module, and then exits. An overheat prevention sensor 8 is installed on one side of the hot-mix block 2 to sense the temperature.

On the other hand, the ground wire 6 is generally fastened to the hot-spring block 2 by means of a screw 7. The hot sink block 2 and the cool sink block 3 are respectively formed with through holes 9. The hot sink block 2 and the cool sink block 3 are fastened to each other by the first bolt 5a, And the lower hot-block block 2 and the cool-sink block 3 are fastened together with the second bolt 5b. In this case, the bolt is generally made of a metal bolt.

As described above, the temperature control fluid flows through the hot-mix block 2 and the cool-sink block 3, and the heat control water (PCW) may be used or an insulation fluid such as DI water may be used have. Since the coolant flowing through the cool sink block 3 directly flows into the object to be cooled, an insulating fluid is used for stabilization. However, the fluid flowing through the hot-mix block 2 has a problem of capacity and cost, (PCW) is generally used.

On the other hand, the hot-mix block 2 and the cool-sink block 3 are generally made of an aluminum material because of good workability and thermal conductivity and economical reasons. At this time, aluminum used as a material of the hot-mix block 2 and the cool sink block 3 is stable in a neutral state, but when a potential difference is generated around the aluminum, And thus, there is a problem that corrosion occurs.

A common metal corrosion is that the atoms on the metal surface leave the crystal lattice and chemically or electrochemically react with the environment. Therefore, in order for metals to corrode, electrons circling around the atoms must first be separated while forming the bonding force of the metal, and the state in which the electrons are separated forms a potential difference. A current flow is generated by a potential difference, which is called a corrosion current. Aluminum is used stably in general neutral environment, but in the presence of halogen ions such as cl ^- , the Al ₂ O ₃ passivation oxide film is destroyed and localized corrosion proceeds. In addition, galvanic corrosion may occur when copper is connected to a metal having a low ionization tendency, such as copper (Cu).

Aluminum is a highly reactive metal, but its corrosion protection is generally excellent due to the protective oxide film formed on its surface. This protective oxide film is known to be stable in a neutral solution of atmospheric pH and pH of 4 to 8.5. However, when the corrosion products are stagnated or accumulated, the local pH in the seawater and fresh water will deviate from the neutral zone, resulting in increased general corrosion and local corrosion. When a few ppm of dissolved copper is present in the water, metal copper is precipitated in the defective area of the aluminum oxide film, and the precipitated copper serves as a local cathode to further promote anodic dissolution of the film defect region.

Therefore, in the cool sink block 3 using the insulating fluid such as DeIonize water (DI water), corrosion is not a serious problem, but the heat dissipating water PCW containing a metal having a low ionization tendency such as copper (Cu) Corrosion is gradually generated in the hot-mix block 2, and there is a problem that corrosion occurs rapidly under a specific pH condition.

Referring again to FIG. 1, corrosion of the conventional heat exchanger including the hot-mix block and the cool-sink block occurs due to the following three reasons.

First, the hot-mix block 2 and the cool-sink block 3 are integrally formed by brazing joints with the block body and the respective inlet / outlet ports 2a and 3a. Since the brassiere joints are formed, , 3a are also basically made of aluminum, so that leakage currents that may be generated from the outside through a connection pipe connected to them are transferred to the respective heat exchange blocks to generate a potential difference and galvanic corrosion occurs.

Secondly, the ground wire 6 is attached to the upper or lower hot-switch block 2. Since each block has a conductor nature, the leakage current is transmitted to each block when a leakage current is generated in any one block, So that corrosion occurs. Especially, in case of leak current in cool sink block, it is transferred to hot-smokable block which is vulnerable to corrosion.

Third, since the hot-swing block 2 and the cool-sink block 3 are fastened together with the hot-mix block 2 and the cool-sink block 3 by metal bolts 5a and 5b on both sides, Each block is electrically connected to each other, and when leakage current is generated, it is transferred to another block, causing a potential difference to cause corrosion.

SUMMARY OF THE INVENTION The present invention has been conceived in view of the above-mentioned problems, and it is an object of the present invention to provide a heat exchanging apparatus, And an object of the present invention is to provide a heat exchanger improved in corrosion prevention function for preventing the occurrence of a potential difference by interrupting a leakage current. Further, according to the present invention, it is possible to improve the corrosion prevention function that further prevents the generation of the potential difference by blocking the flow of the leakage current to the other heat exchange block by electrically insulating each of the heat exchange blocks constituting the heat exchanger, It is another object to provide a heat exchanger.

According to an aspect of the present invention, there is provided an improved heat exchanger including a cool sink block, two temperature control modules installed on opposite sides of the cool sink block, A heat exchanger including a first hot-mix block (12a) and a second hot-mix block (12b) installed on one side of each of the temperature control modules (11) Each of the hot sink blocks 12a and 12b is formed of an aluminum material and the cool sink block 13 and the first and second hot blocks 12a and 12b are connected to an outflow inlet 14 And a connector 18 formed of an insulating material is fastened to the outflow inlet 14 in an assembled manner.

The cool sink block 13 and the first and second hot-lock blocks 12a and 12b sequentially penetrate the first hot-lock block 12a, the cool-sink block 13, and the second hot-lock block 12b And the insulating bolt 15 penetrates the insulating sink 15 so that the insulating bolt 15 does not contact the through hole 22 of the cool sink block 13 and the first and second hot- 12 to be in contact with the through holes 21, 23 of each block 12a, 13, 12b.

Further, a ground wire 16 is provided in the cool sink block 13.

On the other hand, the connector 18 is provided with a coupling rib 19 formed of an insulating material having a screw hole formed therein at its end, and a coupling screw 17 made of an insulating material passing through the screw hole of the coupling rib 19, And is connected to the block 13 and the first and second hot-swing blocks 12a and 12b and between the coupling rib 19 and the surfaces of the cool-sync block 13 and the first and second hot- An O-ring 20 made of an insulating material is disposed.

On the other hand, the thermoelectric module or the heater is applied to the temperature control module 11.

According to the present invention, the connector connected to the connection pipe for supplying / withdrawing the heat exchange fluid from the outside to the heat exchange block (cool sink block, hot sync block) is formed of an insulating material and is mounted on the heat exchange block Therefore, leakage current, which may be generated outside the heat exchanger, is prevented from being transmitted to the heat exchange block through the connection pipe, thereby preventing occurrence of a potential difference in the heat exchange block, thereby preventing corrosion.

Further, when each of the heat exchange blocks constituting the heat exchanger is fastened, the opposite side hot-mix block in one hot-mix block is assembled using insulating bolts, and the cool sink block in the middle is penetrated without contacting the insulating bolt, The electric current is prevented from flowing through the hot-mix block even if a leakage current is generated in the cool-sink block, thereby further suppressing the occurrence of a potential difference, thereby preventing corrosion. Further, by providing the ground wire in the cool sink block in which the insulating fluid circulates, it is more effective in preventing corrosion.

1 is a configuration diagram of a water-cooled heat exchanger to which a conventional thermoelectric module is applied,
FIG. 2 is a schematic view of a heat exchanger having an improved corrosion prevention function according to a preferred embodiment of the present invention. FIG.
FIG. 3 is a conceptual view for explaining an electrical connection relationship of the conventional heat exchanger of FIG. 1;
FIG. 4 is a conceptual diagram for explaining an electrical connection relationship of the heat exchanger with improved corrosion prevention function according to the embodiment of the present invention shown in FIG.

These and other objects, features and other advantages of the present invention will become more apparent by describing in detail preferred embodiments of the present invention with reference to the accompanying drawings. DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENTS Hereinafter, a heat exchanger having an improved corrosion prevention function according to a preferred embodiment of the present invention will be described in detail with reference to the accompanying drawings.

2, the heat exchanger 100 having an improved corrosion prevention function according to an embodiment of the present invention includes two thermoelectric modules 11 as a temperature control module, two hot-mix blocks 12a and 12b, and a cool- 13). For convenience, the upper hot-switch block is referred to as a first hot-lock block 12a and the lower hot-block block is referred to as a second hot-lock block 12b.

2, the heat exchanger 100 includes two hot-mix blocks and one cool-sync block. However, the scope of the present invention is not limited to this, And a thermoelectric module disposed between the cooling sink block and the cooling sink block. It may also include two or more hot-mix blocks and a cool-sync block depending on the degree of temperature regulation required, in which case a plurality of thermoelectric modules may be disposed between the hot-mix block and the cool-sink block.

A thermoelectric element is an electronic device using a Peltier effect. It has a form in which P-type and N-type thermoelectric semiconductors are connected. When a DC power source is connected, an endothermic phenomenon occurs at one end and a heat phenomenon occurs at the other end . The thermoelectric module 11 is formed in a unit shape by connecting a plurality of such thermoelectric elements. The constitution and principle of the thermoelectric element and the thermoelectric module are well known to those of ordinary skill in the art to which the present invention belongs, and a detailed description thereof will be omitted.

The heat exchange block in contact with one end of the thermoelectric module 11 where the endothermic phenomenon occurs is cooled as a cool sink block 13 and the heat exchange block in contact with the other end where heat is generated in the thermoelectric module 11 The hot sink blocks 12a and 12b are heat-dissipated.

In the cool sink block 13, the temperature adjusting fluid flows into the object to be cooled after the heat is taken out (cooled) after circulating and circulating the temperature adjusting fluid. The temperature control fluid also flows into the hot-mix blocks 12a and 12b to circulate and absorb the heat in the hot-mix block heated by the thermoelectric module. Although not shown, an overheat prevention sensor for sensing temperature may be installed on one side of the hot-mix block 12, 12b.

The hot-mix blocks 12a and 12b and the cool-sink block 13 are formed of an aluminum material having good processability and thermal conductivity.

At both end portions of the sides of the hot-mix blocks 12a and 12b and the cool-sink block 13, an outflow inlet 14 is formed to allow the fluid supplied from the outside to flow in and out. The outflow inlet 14 can be freely adjusted in size and the like as necessary. One end of the outflow inlet 14 can be a single inflow of fluid and the other end can be a single outflow of fluid. Conversely, one end of the outflow inlet 14 may be a single outflow of fluid and the other end may be an inflow of fluid.

Then, the connector 18 is fastened to each of the outflow openings 14. A connector (not shown) is connected to the connector 18, so that the temperature control fluid introduced from the outside through the connector flows into the hot-mix block and the cool-sink block through the connector 18 and the outflow inlet 14 and circulates Exchanges heat with each block and exits through the outlet 14 and the connector 18 to the connector.

The connector 18 fastened to the hot-shine blocks 12a and 12b and the cool-sink block 13 is formed of an insulating material. As an example of the insulating material, a polymer resin or the like may be used. However, the insulating material is not limited thereto.

The connector 18 is provided with a coupling rib 19 formed of an insulating material with a screw hole formed therein at an end thereof and a coupling screw 17 made of an insulating material passing through the screw hole of the coupling rib 19, And the hot-melt blocks 12a and 12b. The fastening screw 17 need not be formed of the same material as the connector 18 and can be used without restriction as long as it is a material having appropriate strength required as a material having insulating properties.

An O-ring 20 made of an insulating material is disposed between the coupling ribs 19 and the surfaces of the cool sink block 13 and the hot-mix blocks 12a and 12b. As the material of the O-ring 20, an elastic polymeric resin having an insulating property and a restoring force may be used. The O-ring 20 is disposed between the coupling ribs 19 and the surfaces of the hot-mix blocks 12a and 12b and the cool-sink block 13 so that the connector 18 is connected to the hot-mix blocks 12a and 12b and the cool- And is pressed by the coupling ribs 19 in the process of being coupled with the insulating bolts. Since the O-ring 20 is applied, the connector 18 and the heat exchange block are assembled in a manner avoiding direct contact, thereby further enhancing the insulation effect.

As described above, according to the present invention, the connector 18 is used as an insulating material, and each of the heat exchange blocks (cool sink block, hot sync block) and the connector 18 is connected to the coupling ribs 19, The connection pipe through which the fluid is supplied and the heat exchange blocks of the heat exchanger 100 are insulated so that the leakage current that may be generated from the outside can be prevented from flowing into the heat exchange block through the connection pipe .

As described above, conventionally, each of the heat exchange blocks is integrally formed with an inlet / outlet port made of aluminum material by brazing joint, and the inlet / outlet port is connected to the connection pipe, so that external leakage current flows to the heat exchange block through the connection pipe According to the present invention, since the connector 18 connected to the connection pipe is made of an insulating material and is fastened to the heat exchange block by an assembling method, the leakage current flowing to the heat exchange block is blocked, .

As the temperature controlling fluid flowing in the hot sink blocks 12a and 12b and the cool sink block 13, an insulating fluid such as DeIonize water (DI water) may be used, or a process cooling water (PCW) may be used have. However, as described above, since the temperature control fluid flowing through the cool sink block 13 is a cooling fluid that flows directly into the object to be cooled, an insulating fluid is generally used for stabilization, and the hot-mix blocks 12a and 12b (PCW) is generally used because of problems such as capacity and cost. Therefore, even if the temperature control fluid is used as the heat radiating water, in the heat exchanger according to the present invention, since the heat exchanger 100 is insulated from the outside by the insulating connector 18 and the occurrence of the potential difference can be suppressed, Even if the water contains a metal having a low ionization tendency such as copper (Cu), the corrosion caused thereby can be minimized. Therefore, it is possible to use the heat-radiating water which is cheaper than the insulating fluid as the temperature controlling fluid, thereby minimizing the operating cost.

On the other hand, the cool sink block 13 and the hot-lock blocks 12a and 12b are coupled to each other by the insulating bolt 15. According to a preferred embodiment of the present invention, the through holes 21, 22 and 23 are formed in the first hot-swing block 12a, the cool-sink block 13 and the second hot-swing block 12b, The heat exchanger block 15 sequentially passes through the through holes 21, 22, and 23 to fasten the respective heat exchange blocks.

At this time, it is preferable that the through hole 22 formed in the cool sink block 13 is formed larger in diameter (diameter) than the through holes 21 and 23 formed in the hot-mix blocks 12a and 12b. The insulating bolt 15 is not in contact with the through hole 22 of the cool sink block 13 and is spaced apart from the cool sink block 13 and the through hole 21 of the hot- 23, respectively, to couple the heat exchange blocks. As a result, since the cool sink block and the hot-lock block are electrically isolated from each other, even if a leakage current is generated in the cool-sink block, it is prevented from flowing to the hot-start block. Consequently, do.

On the other hand, in the case where the heat exchanger has a structure including one hot-mix block and one cool-sink block, the heat-exchanger is also coupled by the insulation bolt, but at this time, the insulation bolt is fastened to the cool-sink block and the hot-

Further, the ground wire 16 is installed in the cool sink block 13 through which the insulating fluid flows. In the conventional method, the ground wire is installed in a hot-mix block through which hot water flows, so that leakage current flows to the hot-mix block. However, when the ground wire 16 is attached to the cool sink block 13 using the insulating fluid as in the present invention, Since there is no metal component that will cause corrosion in the insulating fluid even if it is present, there is no significant problem of corrosion in the cool sink block, so that the leakage current is prevented from flowing to the hot sink block and the corrosion is suppressed.

FIG. 3 is a conceptual view for explaining the electrical connection relation of the conventional heat exchanger of FIG. 1, FIG. 4 is a conceptual view for explaining the electrical connection relation of the heat exchanger having the improved corrosion prevention function according to the embodiment of FIG. to be.

3, the hot-melt block 2 and the cool-sink block 3 as described above are arranged in such a manner that the hot-mix block 2 and the cool- Since each of the heat exchange blocks is electrically connected to each other by a bolt made of material, corrosion is generated by generating a potential difference by being transmitted to each block when leakage current is generated. Further, since the ground wire is attached to the upper or lower hot-block block 2 and the blocks are electrically connected to each other, when a leak current is generated in one block (in particular, a cool sink block) So that a potential difference is generated and corrosion occurs.

Generally, since the hot water PCW flows in and out of the hot-mix block 2, the probability of leakage current flowing is relatively small. However, since the cooling fluid flows in the cool sink block 3 and the cooling fluid is to be supplied to the object to be cooled, equipment such as a pump is connected, so that there is a high probability that a leakage current flows relatively. Corrosion does not occur even if a leakage current is generated in the cool sink block 3 due to the flow of the insulating fluid. However, when the leakage current flows through the hot-spring block 2, Since the heat exchange blocks are electrically connected to each other, when there is a leakage current in the cool sink block 3, the heat sink blocks 2 flow into the upper and lower hot-mix blocks 2, resulting in corrosion due to the potential difference.

4, the heat exchanger 100 according to the present invention has a structure in which the insulating bolt is assembled to the second hot-mix block 12b via the first hot-mix block 12a, and a cooling sink block 12b are not in contact with each other, the cool sink block 13 and the hot-lock blocks 12a, 12b are insulated from each other, and the ground wire is installed in the cool sink block 13. [ Therefore, even if there is a leakage current in the cool sink block 13, it is prevented from flowing to the hot-mix blocks 12a and 12b, thereby preventing corrosion.

In the meantime, in the preferred embodiment of the present invention, the temperature control module applied to the heat exchanger is exemplified and described as being the thermoelectric module 11, but the scope of the present invention is not limited thereto. For example, . When the heater is applied, the heating fluid of the insulating oil chain flows to both blocks to absorb the heat and go to the heating object.

As described above, according to the present invention, the connector connected to the connection pipe for supplying / recovering the heat exchange fluid from the outside to the heat exchange block (cool sink block, hot sync block) is formed of an insulating material, The leakage current that may be generated outside the heat exchanger is prevented from being transmitted to the heat exchange block through the connection pipe, thereby preventing the occurrence of a potential difference in the heat exchange block, thereby preventing corrosion have.

In addition, when the heat exchange blocks constituting the heat exchanger are fastened, the opposite side hot-mix block is assembled by using the hot-side block as an insulation bolt in one of the hot-mix blocks, and the cool- By providing electrical insulation between the ground wires and the cooling sink block in which the insulating fluid is circulated, it is possible to prevent the cool sink block from flowing to the hot-spring block even if there is leakage current, which is likely to generate leakage current. .

Although the preferred embodiments of the present invention have been described, the present invention is not limited to the specific embodiments described above. It will be apparent to those skilled in the art that numerous modifications and variations can be made in the present invention without departing from the spirit or scope of the appended claims. And equivalents should also be considered to be within the scope of the present invention.

11. Temperature control module (thermoelectric module) 12a, 12b. HotSync Block
13. Cool sink block 14. Outlet entrance
15. Insulation bolt 16. Ground wire
17. Tightening screw 18. Connector
19. Engaging rib 20. O-ring
21, 22, 23. Through hole 100. Heat exchanger with improved corrosion protection

Claims (10)

A plurality of temperature control modules 11 installed on both sides of the cooling sink block 13 to face each other and a plurality of temperature control modules 11 In a heat exchanger (100) comprising a hot and cold block (12a) and a second hot and cold block (12b)
The cool sink block 13 and the first and second hot-lock blocks 12a and 12b are made of aluminum,
The cool sink block 13 and the first and second hot-mix blocks 12a and 12b are respectively formed with an outflow inlet 14 through which a temperature-regulating fluid flows therein. And a connector 18 formed of an insulating material to which a connection pipe for connecting and disconnecting the temperature control fluid is connected are each assembled in an assembling manner so that leakage current generated from the outside is supplied to the cool sink block 13 and the first and second hot- 12a, 12b of the heat exchanger.
The method according to claim 1,
The cool sink block 13 and the first and second hot-lock blocks 12a and 12b sequentially penetrate the first hot-lock block 12a, the cool-sink block 13, and the second hot- Are connected to each other by an insulating bolt (15)
The insulating bolt 15 penetrates through the through hole 22 of the cool sink block 13 so as to be in contact with the through holes 21 and 23 of the first and second hot- Wherein the blocks (12a, 13, 12b) are combined.
The method according to claim 1,
Wherein the cool sink block (13) is provided with a ground wire (16).
The method according to claim 1,
The connector 18 is provided with a coupling rib 19 formed of an insulating material having a screw hole formed therein and a coupling screw 17 made of an insulating material passing through the screw hole of the coupling rib 19, 13 and the first and second hot-swing blocks 12a, 12b,
Characterized in that an O-ring (20) made of an insulating material is disposed between the coupling rib (19) and the surface of the cool sink block (13) and the first and second hot-mix blocks (12a, 12b) group.
The method according to claim 1,
Wherein the temperature control module (11) is a thermoelectric module or a heater.
A heat exchanger including a temperature control module, a cool sink block installed on one side of the temperature control module, and a hot-shine block installed on the other side of the temperature control module,
The cool sink block and the hot-mix block are each formed of an aluminum material,
Wherein the cool sink block and the hot-mix block are respectively formed with an outflow inlet through which a temperature-regulating fluid flows in and out, and a connector formed of an insulating material is fastened to the outflow inlet in an assembled manner. heat transmitter.
The method according to claim 6,
Wherein the cool sink block and the hot-mix block are coupled to each other by an insulating bolt made of an insulating material.
The method according to claim 6,
Wherein the cooling sink block is provided with a ground wire.
The method according to claim 6,
Wherein the connector has a coupling rib of an insulating material formed with a screw hole and is fastened to the cool sink block and the hot sink block by a fastening screw of an insulating material passing through a screw hole of the coupling rib,
And an O-ring of an insulating material is disposed between the coupling rib and the surface of the cool sink block and the hot-mix block.
The method according to claim 6,
Wherein the temperature control module is a thermoelectric module or a heater.

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