CN102621177B - Heat tube testing machine, and heat tube testing system using the same - Google Patents

Abstract

A heat tube testing machine comprises a heating module heating a heat tube to be tested and a radiating module radiating the heat tube to be tested, the heating module comprises a heating copper block heating the heat tube to be tested, the radiating module comprises a radiating copper block, a heat conducting wafer, a heating absorbing copper block and a fan which are sequentially superposed together, two ends of the heat tube to be tested are disposed on the heating copper block and the radiating copper block respectively, the radiating copper block transmits heat absorbed from the heat tube to be tested to the fan by sequentially passing through the heat conducting wafer and the heat absorbing copper block, and the fan cools the heat absorbing copper block. The invention also provides a heat tube testing system having the heat tube testing machine. The heat tube testing machine and the heat tube testing system have good radiating effects.

Description

Heat pipe test instrument and use the heat pipe test system of this heat pipe test instrument

Technical field

The present invention relates to a kind of heat pipe test instrument and use the heat pipe test system of this heat pipe test instrument.

Background technology

In recent years, along with the raising of main frame speed and performance, inscribe more and more outstanding between the heat radiation of its inside.Most computers host computer heat pipe, heating radiator and fan etc. combine and dispel the heat.Main heater element on main frame is generally central processing unit and video card etc.Heat pipe contacts with this heater element such as central processing unit and/or video card the heat siphoning away above-mentioned heater element, is dispelled the heat by the heat on heat pipe subsequently via heating radiator and fan etc.Therefore, the heat conductivility of heat pipe is the important indicator judging heat pipe quality.

When the heat conductivility of opposite heat tube is tested, heating module is generally needed to heat to simulate the pyrotoxin such as central processing unit and/or video card opposite heat tube, utilize heat radiation module to carry out opposite heat tube to dispel the heat, computing machine is sent to gathered the temperature of this heating module and heat radiation module by temperature acquisition device after, computing machine then carries out Treatment Analysis to the temperature data of temperature acquisition device collection, to draw the test result of this heat pipe.

Existing heat radiation module generally only adopts the water (water-cooling pattern) of fan (air cooling way) or flowing to carry out opposite heat tube and directly dispel the heat.But the radiating effect of described radiating mode is bad, affect the performance test of heat pipe.

Summary of the invention

In view of this, be necessary that providing a kind of has great heat radiation effect carries out accurately test heat pipe test instrument with opposite heat tube performance.

Separately, there is a need to provide a kind of heat pipe test system with above-mentioned heat pipe test instrument.

A kind of heat pipe test instrument, comprise and treat heating module that calorimetric pipe carries out heating and treat the heat radiation module that calorimetric pipe carries out dispelling the heat, described heating module comprises the heating copper billet carrying out heating for treating calorimetric pipe, described heat radiation module comprises the heat radiation copper billet be stacked at successively together, heat-conducting chip, heat absorption copper billet and fan, the two ends of described heat pipe to be measured are positioned on described heating copper billet and heat radiation copper billet respectively, the heat absorbed from heat pipe to be measured is passed to described fan by heat-conducting chip and heat absorption copper billet by described heat radiation copper billet successively, absorb heat described in described fan cooled copper billet.

A kind of heat pipe test system, performance for treating calorimetric pipe is tested, described heat pipe test system comprises heat pipe test instrument, control box and computing machine, described heat pipe test instrument comprises to be treated heating module that calorimetric pipe carries out heating and treats the heat radiation module that calorimetric pipe carries out dispelling the heat, described heating module comprises the heating copper billet carrying out heating for treating calorimetric pipe, described heat radiation module comprises the heat radiation copper billet be stacked at successively together, heat-conducting chip, heat absorption copper billet and fan, the two ends of described heat pipe to be measured are positioned on described heating copper billet and heat radiation copper billet respectively, the heat absorbed from heat pipe to be measured is passed to described fan by heat-conducting chip and heat absorption copper billet by described heat radiation copper billet successively, absorb heat described in described fan cooled copper billet, described control box is sent to described computing machine after gathering the temperature data of described heating copper billet and heat radiation copper billet, and described computing machine carries out Treatment Analysis to draw the test result to this properties of hot pipe to described temperature data.

Described heat pipe test system conducts heat on described heat pipe to be measured to described fan by described heat radiation copper billet, heat-conducting chip and the heat absorption copper billet of arranging, effectively improve the radiating effect of the heat treated on calorimetric pipe, thus improve the accuracy of opposite heat tube performance test.

Accompanying drawing explanation

Fig. 1 is the stereographic map of the heat pipe test system of better embodiment of the present invention.

Fig. 2 is the three-dimensional assembly diagram of the heat pipe test instrument of better embodiment of the present invention.

Fig. 3 is the three-dimensional exploded view of heat pipe test instrument shown in Fig. 2.

Main element symbol description

Heat pipe test system 100

Heat pipe test instrument 10

Heating module 11

Heating copper billet 111

Heat insulation 112

Mounting groove 1121

First mounting hole 1123

Fixed block 113

Second mounting hole 1131

Heating rod 114

Fire end back up pad 115

Fire end base 116

Heat radiation module 12

Heat radiation copper billet 121

Thermal insulation board 122

Pilot hole 1221

Heat-conducting chip 123

Heat insulation loop 124

Heat absorption copper billet 125

Fan 126

Screw 1261

Assembling block 127

Accepting hole 1271

Assembled shaft 128

Radiating end base 129

Radiating end back up pad 1291

Fixing module 13

Cylinder 131

Briquetting 133

Web joint 135

Loading plate 14

Regulate module 15

Connection Block 151

Supporting seat 153

Fitting recess 1531

Rotating shaft 155

Set bolt 157

Pointer 159

Base plate 16

Start/stop button 161

Pilot lamp 163

Control box 30

Power supply module 31

Attaching plug 311

Temperature data acquisition module 33

Acting thermocouple plug 331

Computing machine 50

Embodiment

Refer to Fig. 1, heat pipe test system 100 of the present invention is tested for the heat transfer property treating calorimetric pipe.The control box 30 that the heat pipe test system 100 of better embodiment of the present invention comprises heat pipe test instrument 10, be electrically connected with heat pipe test instrument 10 and the computing machine 50 be electrically connected with control box 30.

Refer to Fig. 2 and Fig. 3, described heat pipe test instrument 10 comprises heating module 11, heat radiation module 12, fixing module 13, loading plate 14, regulates module 15 and base plate 16.Wherein, described heating module 11 heats for the one end for the treatment of calorimetric pipe; Described heat radiation module 12 is for dispelling the heat to the other end of described heat pipe to be measured; Described fixing module 13 is for being fixed on described heating module 11 and heat radiation module 12 by described heat pipe to be measured; Described loading plate 14 is for carrying described heating module 11 and heat radiation module 12; Described adjustment module 15 for regulating the angle of described loading plate 14 and surface level, thus regulates described heating module 11 and heat radiation module 12 from surface level angle to adapt to the test request of different heat pipe to be measured.

In this better embodiment, the quantity of described heating module 11 is two.Described two heating modules 11 are disposed adjacent.See also Fig. 3, each heating module 11 comprises heating copper billet 111, heat insulation 112, fixed block 113, heating rod 114 (as shown in Figure 3), fire end back up pad 115 and is fixed in the fire end base 116 of described loading plate 14.Described heating copper billet 111, heat insulation 112 and fixed block 113 successively folded establishing are fixed in together.Described heating copper billet 111 is for supporting described heat pipe to be measured and heating this heat pipe to be measured.The surface that described heat insulation 112 deviates from this fixed block 113 offers mounting groove 1121, for installing described heating copper billet 111.Described heat insulation 112 offers through the first mounting hole 1123 to this mounting groove 1121 towards the surface of this fixed block 113.Described fixed block 113 offers second mounting hole 1131 coaxial with this first mounting hole 1123.Described heating rod 114 one end is contained in this second mounting hole 1131, and the other end is contained in this second mounting hole 1131, and contacts with described heating copper billet 111 in mounting groove 1121, to heat this heating copper billet 111.Described fire end back up pad 115 respectively with described fixed block 113 and fire end base 116 Joint, with this, described fixed block 113 and described fire end base 116 are connected together.

Described heat radiation module 12 comprises the heat radiation copper billet 121, heat-conducting chip 123, heat absorption copper billet 125 and the fan 126 that are stacked at successively together, the two ends of described heat pipe to be measured are positioned on described heating copper billet 111 and heat radiation copper billet 121 respectively, the heat absorbed from heat pipe to be measured is passed to described fan 126 by heat-conducting chip 123 and heat absorption copper billet 125 by described heat radiation copper billet 121 successively, is discharged by heat eventually through described fan 126.

In this better embodiment, described heat radiation module 12 also comprises thermal insulation board 122, heat insulation loop 124, assembling block 127, assembled shaft 128, is fixed in the radiating end base 129 of described loading plate 14 and is fixed in the radiating end back up pad 1291 of described radiating end base 129.

Described thermal insulation board 122 is fixed in described assembling block 127; The through pilot hole 1221 offered for assembling described heat radiation copper billet 121 on described thermal insulation board 122.Described heat insulation loop 124 is roughly in frame shaped; This heat insulation loop 124 accommodates described heat-conducting chip 123 in its framework.Described fan 126 is fixed in the another side of described assembling block 127 relative to described thermal insulation board 122.Particularly, described fan 126 is fixed on described assembling block 127 by the screw 1261 that its four end angles are arranged respectively.The bottom surface of described fan 126 is also carried on described radiating end base 129.

Throughly on described assembling block 127 offer accepting hole 1271.Described heat insulation loop 124 and the heat-conducting chip 123 be assemblied in this heat insulation loop 124 are partially housed in this accepting hole 1271.Described heat radiation copper billet 121 one end is assemblied on this thermal insulation board 122, and the other end is contained in described accepting hole 1271 through described pilot hole 1221, and contacts with the heat-conducting chip 123 be assemblied in described heat insulation loop 124.Described heat absorption copper billet 125 is arranged between described assembling block 127 and described fan 126, and this heat absorption copper billet 125 1 side contacts with the heat-conducting chip 123 in described heat insulation loop 124, and another side contacts with described fan 126.So, be stacked at successively together between described heat radiation copper billet 121, heat-conducting chip 123, heat absorption copper billet 125 and fan 126.The heat absorbed from heat pipe to be measured is passed to described fan 126 by heat-conducting chip 123 and heat absorption copper billet 125 by described heat radiation copper billet 121 successively, is discharged by heat eventually through described fan 126.Surface of contact between described heat radiation copper billet 121, heat-conducting chip 123, heat absorption copper billet 125 and fan 126 adjacent pairs can be connected by coated with thermally conductive cream, to increase heat transfer efficiency.In addition, described thermal insulation board 122 and heat insulation loop 124 are passed to described assembling block 127 for avoiding the heat dispelled the heat described in this on copper billet 121, heat-conducting chip 123 and heat absorption copper billet 125, avoid affecting radiating effect with this.

Described assembled shaft 128 is fixed between described radiating end base 129 and described assembling block 127, to support described assembling block 127.In this better embodiment, the quantity of described assembled shaft 128 is four, and assembled shaft 128 described in each root is fixed in an end angle of this radiating end base 129.

In this better embodiment, the quantity of described fixing module 13 is described heating module 11 and heat radiation module 12 quantity sum, namely each heating module 11 and heat radiation module 12 all installs a described fixing module 13.Each fixing module 13 comprises cylinder 131, the briquetting 133 driven by this cylinder 131 and the web joint 135 being solidly connected to this cylinder 131.Described fixing module 13 is solidly connected to the fire end back up pad 115 of described heating module 11 and the radiating end back up pad 1291 of described heat radiation module 12 respectively by described web joint 135.Described briquetting 133 aligns with described heating copper billet 111 and the copper billet 121 that dispels the heat respectively.Described cylinder 131 drives briquetting 133 to press to be carried on the heat pipe to be measured on described heating copper billet 111 and heat radiation copper billet 121, to be fixed on by heat pipe to be measured on described heating copper billet 111 and heat radiation copper billet 121.

Described adjustment module 15 comprises Connection Block 151, supporting seat 153, rotating shaft 155, set bolt 157 and pointer 159.The quantity of described Connection Block 151, supporting seat 153, rotating shaft 155 and set bolt 157 is two.Described two Connection Blocks 151 are solidly connected to the two ends of described loading plate 14 respectively; Described two supporting seats 153 are fixed in the two ends of described base plate 16 respectively; One end of rotating shaft 155 described in each is fixed in a Connection Block 151, and the other end is articulated in a supporting seat 153.So, namely described loading plate 14 is assemblied on described supporting seat 153 rotationally.Throughly on supporting seat 153 described in each offer fitting recess 1531, this fitting recess 1531 assembles described set bolt 157 rotationally.In this better embodiment, described fitting recess 1531 is in arc-shaped.The end of this set bolt 157 is bolted in described Connection Block 151; After described loading plate 14 drives described Connection Block 151 to turn to required position relative to supporting seat 153, regulate described set bolt 157 described Connection Block 151 and loading plate 14 can be fixed on the position described in this.

Described pointer 159 is fixed in the end face of one of them rotating shaft 155 and is positioned at the side of described supporting seat 153.The periphery of this fitting recess 1531 of flank abutment of described supporting seat 153 is spaced apart is provided with multiple pointer scale (not shown), to represent the angle that this loading plate 14 rotates.Namely, when turning an angle under the effect of described loading plate 14 in external force, its pointer 159 driving this rotating shaft 155 by Connection Block 151 and be fixed in this rotating shaft 155 rotates, and namely this pointer 159 points to corresponding pointer scale, can indicate the angle of this loading plate 14 upset accurately, easily.

Described base plate 16 is provided with start/stop button 161 and two pilot lamp 163.Described start/stop button 161 and two pilot lamp 163 are all electrically connected with described computing machine 50.Described start/stop button 161 is for controlling beginning and the end of test.Described two pilot lamp 163 are respectively red light and green light, when red when heat pipe to be measured is defective, green light when heat pipe to be measured is qualified.

Please consult Fig. 1 again, described control box 30 comprises power supply module 31 and temperature data acquisition module 33.Described power supply module 31 comprises multiple attaching plug 311.One of them attaching plug 311 provides operating voltage for described fan 126; The heating rod 114 that remaining attaching plug 311 is respectively described heating module 11 provides electric energy, generates heat to make described heating rod 114.Described temperature data acquisition module 33 comprises multiple acting thermocouple plug 331.Described multiple acting thermocouple plug 331 is connected to the heating copper billet 111 of described heating module 11 or the heat radiation copper billet 121 of heat radiation module 12, to gather the temperature on this heating copper billet 111 and this heat radiation copper billet 121 respectively by thermocouple wire (not shown).

Described computing machine 50 provides graphic user interface, user by this interface can parameters, select determinating mode and check test result.Whether described computing machine 50 carries out Treatment Analysis for the temperature data gathered described temperature data acquisition module 33, qualified to judge the test of this heat pipe, and test result is sent to the instruction that described pilot lamp 163 carries out test result.

Refer to Fig. 1 and Fig. 3, when assembling described heat pipe test system 100, first assemble one of them heating module 11 of described heat pipe test instrument 10: be installed in by described heating copper billet 111 in the mounting groove 1121 of described heat insulation 112; Be contained in the second mounting hole 1131 of this fixed block 113 by described heating rod 114 one end again, the other end is contained in the second mounting hole 1131 of this heat insulation 112, and contacts with described heating copper billet 111 in mounting groove 1121; Then described fixed block 113 is fixed to described fire end back up pad 115, described fire end back up pad 115 is solidly connected to described fire end base 116; Finally described fire end base 116 is solidly connected to described loading plate 14.Then assemble in the same way described in another and heat module 11, and make two described heating modules 11 adjacent, the heating copper billet 111 of described two heating modules 11 is positioned at same level.

Assemble described heat radiation module 12 subsequently: be fixed in by described radiating end base 129 on described loading plate 14; Then assembled shaft 128 described in each root is fixed in an end angle of this radiating end base 129; Then described fan 126 is positioned on this radiating end base 129, described heat absorption copper billet 125 is positioned on this fan 126, after described heat-conducting chip 123 being contained in this heat insulation loop 124, then be positioned on this heat absorption copper billet 125; Next described fan 126 is fixed on described assembling block 127 by the screw 1261 that its four end angles are arranged respectively, again by this assembling block 127 and described assembled shaft 128 Joint, and this heat insulation loop 124 and heat-conducting chip 123 is made to be contained in the accepting hole 1271 of this assembling block 127; Next described thermal insulation board 122 is fixed in described assembling block 127, subsequently described heat radiation copper billet 121 one end is assemblied on this thermal insulation board 122, the other end is contained in described accepting hole 1271 through described pilot hole 1221, and contacts with the heat-conducting chip 123 be assemblied in described heat insulation loop 124; Finally described radiating end back up pad 1291 is fixed on described radiating end base 129.

Then on each heating module 11 and heat radiation module 12, all install a described fixing module 13, and described briquetting 133 is aligned with described heating copper billet 111 and the copper billet 121 that dispels the heat respectively.Then described two Connection Blocks 151 are solidly connected to respectively the two ends of described loading plate 14; Described two supporting seats 153 are fixed in the two ends of described base plate 16 respectively; One end of rotating shaft 155 described in each is fixed in a Connection Block 151, and the other end is articulated in a supporting seat 153; And after being fixed by described set bolt 157 between this Connection Block 151 and described supporting seat 153, described pointer 159 being fixed on the end face of described rotating shaft 155, namely described heat pipe test instrument 10 has been assembled.

Subsequently described control box 30 is electrically connected to described computing machine 50; Again multiple attaching plugs 311 of control box 30 are connected to described fan 126 and heating rod 114 respectively by power lead, finally acting thermocouple plug described in each 331 are connected to a thermocouple wire.Namely described heat pipe test system 100 has been assembled.

Described heat pipe test system 100 conducts heat on described heat pipe to be measured to described fan 126 by described heat radiation copper billet 121, heat-conducting chip 123 and the heat absorption copper billet 125 of arranging, effectively improve the radiating effect of the heat treated on calorimetric pipe, thus improve the accuracy of opposite heat tube performance test.

Claims (12)

1. a heat pipe test instrument, comprise and treat heating module that calorimetric pipe carries out heating and treat the heat radiation module that calorimetric pipe carries out dispelling the heat, described heating module comprises the heating copper billet carrying out heating for treating calorimetric pipe, it is characterized in that: described heat radiation module comprises the heat radiation copper billet be stacked at successively together, heat-conducting chip, heat absorption copper billet and fan, the two ends of described heat pipe to be measured are positioned on described heating copper billet and heat radiation copper billet respectively, the heat absorbed from heat pipe to be measured is passed to described fan by described heat-conducting chip and described heat absorption copper billet by described heat radiation copper billet successively, absorb heat described in described fan cooled copper billet, described heat radiation module also comprises assembling block and is fixed in the thermal insulation board of described assembling block, throughly on described thermal insulation board offer pilot hole, described assembling block offers accepting hole, described heat radiation copper billet one end is assemblied on this thermal insulation board, and the other end is contained in described accepting hole through described pilot hole.

2. heat pipe test instrument as claimed in claim 1, is characterized in that: described heat radiation module also comprises the heat insulation loop be partially housed in described accepting hole, and described heat insulation loop is frame shaped, and described heat-conducting chip is contained in described heat insulation loop.

3. heat pipe test instrument as claimed in claim 1, it is characterized in that: described heat radiation module also comprises radiating end base and many assembled shaft, assembled shaft is fixed between described radiating end base and described assembling block, to support described assembling block.

4. heat pipe test instrument as claimed in claim 1, it is characterized in that: described heating module also comprises heat insulation and heating rod, this heat insulation offers the first mounting hole, this heating rod is contained in this first mounting hole, and described Heated Copper is packaged to be assigned on this heat insulation and to contact with this heating rod.

5. heat pipe test instrument as claimed in claim 4, it is characterized in that: described heating module also comprises fixed block, back up pad and fire end base, described heat insulation is fixed in described fixed block, described back up pad is fixed in described fixed block and fire end base respectively, so that described fixed block is fixed in described fire end base.

6. heat pipe test instrument as claimed in claim 1, is characterized in that: described heat pipe test instrument also comprises the multiple fixing module for fixing described heat pipe to be measured, and each heating module and heat radiation module all install a described fixing module; Fix module described in each and comprise a cylinder and the briquetting by this air cylinder driven, described air cylinder driven briquetting presses to the heat pipe to be measured be carried on described heating copper billet and heat radiation copper billet, to be fixed on by heat pipe to be measured on described heating copper billet and heat radiation copper billet.

7. heat pipe test instrument as claimed in claim 1, it is characterized in that: described heat pipe test instrument also comprises the loading plate regulating module and be assemblied in rotationally on this adjustment module, described heating module and heat radiation module are all fixed on this loading plate, described adjustment module comprises supporting seat, rotating shaft and is fixed in the Connection Block of described loading plate, described rotating shaft one end is fixed in described Connection Block, and the other end is articulated in described rotating shaft.

8. heat pipe test instrument as claimed in claim 7, it is characterized in that: described adjustment module also comprises the set bolt for described Connection Block being fixed on described supporting seat, throughly on described supporting seat offer fitting recess, described set bolt one end is assemblied in this fitting recess rotationally, and the other end is bolted in described Connection Block.

9. heat pipe test instrument as claimed in claim 7, it is characterized in that: described adjustment module also comprises pointer, this pointer is fixed in the end face of described rotating shaft, the spaced surface of described supporting seat offers multiple pointer scale, when turning an angle under the effect of described loading plate in external force, its indicators turn being driven this rotating shaft by Connection Block and be fixed in this rotating shaft, namely this pointer points to corresponding pointer scale.

10. a heat pipe test system, performance for treating calorimetric pipe is tested, described heat pipe test system comprises heat pipe test instrument, control box and computing machine, described heat pipe test instrument comprises to be treated heating module that calorimetric pipe carries out heating and treats the heat radiation module that calorimetric pipe carries out dispelling the heat, described heating module comprises the heating copper billet carrying out heating for treating calorimetric pipe, it is characterized in that: described heat radiation module comprises the heat radiation copper billet be stacked at successively together, heat-conducting chip, heat absorption copper billet and fan, the two ends of described heat pipe to be measured are positioned on described heating copper billet and heat radiation copper billet respectively, described heat radiation module also comprises assembling block and is fixed in the thermal insulation board of described assembling block, throughly on described thermal insulation board offer pilot hole, described assembling block offers accepting hole, described heat radiation copper billet one end is assemblied on this thermal insulation board, the other end is contained in described accepting hole through described pilot hole, the heat absorbed from heat pipe to be measured is passed to described fan by heat-conducting chip and heat absorption copper billet by described heat radiation copper billet successively, and absorb heat described in described fan cooled copper billet, described control box is sent to described computing machine after gathering the temperature data of described heating copper billet and heat radiation copper billet, and described computing machine carries out Treatment Analysis to draw the test result to this properties of hot pipe to described temperature data.

11. heat pipe test systems as claimed in claim 10, is characterized in that: described control box comprises multiple acting thermocouple plug, and described multiple acting thermocouple plug is for gathering the temperature on described heating copper billet and heat radiation copper billet.

12. heat pipe test systems as claimed in claim 10, is characterized in that: described control box is also provided with multiple attaching plug, and being respectively used to provides operating voltage for described fan and heating copper billet is provided to the electric energy of heating.