CN213932159U - Heat pipe type waste heat recovery device - Google Patents

Abstract

The utility model relates to the technical field of heat pipe heat exchange, and discloses a heat pipe type waste heat recovery device, which comprises a heat exchange mechanism, an air inlet mechanism and a waste heat recovery mechanism arranged on the heat exchange mechanism, wherein the air inlet mechanism is arranged on one side of the heat exchange mechanism; the waste heat recovery mechanism comprises a top plate, a heat pipe, adjusting components, a waste heat absorber, a conveying pipe and a preheating sleeve, wherein the top plate is installed on the top surface of the heat exchange mechanism, the heat pipe is installed at the center of the top surface of the top plate, and the top surface of the top plate is provided with four adjusting components. The utility model discloses carry out recycle with the inside waste heat of heat transfer mechanism through the heat pipe, concentrate the waste heat through the waste heat absorber, then heat treatment is carried out to the water of preheating the cover inside with the waste heat through the conveyer pipe for get into the inside gas of heat transfer mechanism and obtain better preheating effect, can effectually ensure that the inside heat of heat transfer mechanism obtains recycle.

Description

Heat pipe type waste heat recovery device

Technical Field

The utility model relates to a heat pipe heat transfer technical field specifically is a heat pipe formula waste heat recovery device.

Background

The super heat conductivity and the isothermal property of the heat pipe make the heat pipe become an ideal tool for controlling the temperature in the aerospace technology, the heat pipe heat exchanger has the advantages of high heat transfer efficiency, compact structure, small pressure loss, being beneficial to controlling dew point corrosion and the like, and the heat pipe transfers heat through evaporation and condensation of working media in a totally-enclosed vacuum pipe shell, thereby having a series of advantages of extremely high heat conductivity, good isothermal property, capability of randomly changing heat transfer areas on the cold side and the hot side, capability of transferring heat remotely, capability of controlling the temperature and the like. The disadvantages are poor oxidation resistance and high temperature resistance. The defect can be solved by installing a set of ceramic heat exchanger at the front part, and the ceramic heat exchanger well solves the problems of high temperature resistance and corrosion resistance. The energy-saving device is widely applied to industries such as metallurgy, chemical industry, oil refining, boilers, ceramics, transportation, light textile, machinery and the like at present, and has remarkable economic benefit as energy-saving equipment for waste heat recovery and heat energy utilization in the process.

The working medium at the evaporation section in the heat pipe is boiled or evaporated after being heated, the heat of an external heat source is absorbed, latent heat of vaporization is generated and is changed from liquid to steam, the generated steam flows to the condensation section under the action of a certain pressure difference in the pipe, the steam is condensed into liquid when meeting the cold wall surface and an external cold source and releases latent heat of vaporization at the same time and is transmitted to the external cold source through the pipe wall, and the condensed liquid flows back to the evaporation section to be evaporated again under the action of gravity (or a liquid absorption core). The heat transfer and exchange of the external cold and hot media are realized by reciprocating in this way.

The phenomenon that the heat in partial heat exchanger can run off when the current heat exchanger is used, and then the problem of heat loss is caused, and the heat can not be effectively recycled.

SUMMERY OF THE UTILITY MODEL

The utility model provides a heat pipe formula waste heat recovery device adopts the heat pipe technique, carries out recycle with the inside waste heat of heat exchanger, has energy saving's advantage, has solved among the prior art unable difficult problem that carries out recycle to the inside waste heat of heat exchanger.

In order to solve the above problem, the utility model provides a following technical scheme: a heat pipe type waste heat recovery device comprises a heat exchange mechanism, an air inlet mechanism and a waste heat recovery mechanism arranged on the heat exchange mechanism, wherein the air inlet mechanism is arranged on one side of the heat exchange mechanism;

waste heat recovery mechanism includes roof, heat pipe, adjusting part, waste heat absorber, conveyer pipe and preheats the cover, the roof install in heat exchange mechanism's top surface, the heat pipe install in the center department on roof top surface, four are installed on the top surface of roof adjusting part, and four the adjusting part ring is established the lateral wall of heat pipe, four adjusting part's top all with waste heat absorber's basal surface is connected, waste heat absorber's top surface is installed the conveyer pipe, the conveyer pipe is kept away from waste heat absorber's one end is installed preheat the cover, preheat the cover and install intake mechanism is last.

Preferably, the adjusting assembly comprises a hollow sleeve, a first telescopic rod, a sliding block, a threaded rod, a second threaded sleeve, a second telescopic rod, a third threaded sleeve, a second sliding block and a clamping block, a sliding groove is vertically formed in the front end face of the hollow sleeve, the first telescopic rod is sleeved at the bottom end of the hollow sleeve, the bottom end of the first telescopic rod is connected with the top surface of the top plate, the sliding block is mounted at the top of the front end face of the first telescopic rod and located in the sliding groove, the threaded rod is movably sleeved at the top end of the first telescopic rod, the second threaded sleeve is sleeved on the outer surface of the threaded rod, the bottom surface of the second threaded sleeve is in contact with the top surface of the first telescopic rod, the second telescopic rod is movably sleeved at the top end of the threaded rod, and the top end of the second telescopic rod penetrates through the top surface of the hollow sleeve, the outer surface of the threaded rod is in threaded sleeve connection with the third threaded sleeve, the top surface of the third threaded sleeve is in contact with the bottom surface of the second telescopic rod, the second sliding block is mounted on the front end face of the second telescopic rod and located in the sliding groove, the clamping block is mounted at the top end of the second telescopic rod, and the top surface of the clamping block is connected with the bottom surface of the waste heat absorber.

Preferably, the air inlet mechanism comprises a first air inlet pipe, a magnetic suction assembly and a second air inlet pipe, the first air inlet pipe is installed on one side of the heat exchange mechanism, the first air inlet pipe is far away from one end of the heat exchange mechanism, the magnetic suction assembly is far away from one side of the first air inlet pipe, the second air inlet pipe is installed on one side of the second air inlet pipe, and the preheating sleeve is sleeved on the outer surface of the second air inlet pipe.

Preferably, the subassembly is inhaled including positive pole magnetism piece and negative pole magnetism piece of inhaling, positive pole magnetism piece install in the one end of first intake pipe, one side of negative pole magnetism piece with the one end of second intake pipe is connected, positive pole magnetism piece with negative pole magnetism piece magnetism is inhaled and is connected.

Preferably, heat transfer mechanism includes heat exchanger shell, heat transfer fin, first adapter sleeve and second adapter sleeve, the top surface of heat exchanger shell with the basal surface of roof is connected, a plurality ofly is installed to the inner chamber of heat exchanger shell heat transfer fin, install one side of heat exchanger shell first adapter sleeve, the heat exchanger shell is kept away from one side of first adapter sleeve is installed the second adapter sleeve.

Preferably, one side of the second connecting sleeve, which is far away from the heat exchange mechanism, is connected with a first air outlet pipe, and one end of the first air outlet pipe, which is far away from the heat exchange mechanism, is connected with a second air outlet pipe through the magnetic suction assembly.

The beneficial effects of the utility model are that, through the setting of waste heat recovery mechanism, the inside heat transfer fin of heat transfer mechanism carries out heat transfer treatment and discharges through first outlet duct and second outlet duct, carry out recycle through the heat pipe with the inside waste heat of heat transfer mechanism simultaneously, concentrate the waste heat through the waste heat absorber, then heat treat the inside water of cover with the waste heat through the conveyer pipe to preheating for get into the inside gas of heat transfer mechanism and obtain better preheating effect, can effectually ensure that the inside heat of heat transfer mechanism obtains recycle.

Drawings

In order to more clearly illustrate the embodiments of the present invention or the technical solutions in the prior art, the drawings used in the description of the embodiments or the prior art will be briefly described below, it is obvious that the drawings in the following description are only some embodiments of the present invention, and for those skilled in the art, other drawings can be obtained according to these drawings without creative efforts.

Fig. 1 is a schematic structural view of the present invention;

FIG. 2 is a schematic structural diagram of an adjusting assembly of the present invention;

FIG. 3 is a schematic view of the internal structure of the heat exchange mechanism of the present invention;

fig. 4 is a schematic structural view of the middle magnetic attraction assembly of the present invention.

The reference numbers in the figures illustrate: 1. a heat exchange mechanism; 101. a heat exchanger housing; 102. heat exchange fins; 103. a first connecting sleeve; 104. a second connecting sleeve; 2. a first intake pipe; 3. a magnetic component; 301. a positive magnetic block; 302. a negative magnetic suction block; 4. a second intake pipe; 5. a first air outlet pipe; 6. a second air outlet pipe; 7. A top plate; 8. a heat pipe; 9. an adjustment assembly; 901. hollow sleeve; 902. a first telescopic rod; 903. a slider; 904. a threaded rod; 905. a second threaded sleeve; 906. a second telescopic rod; 907. a third thread bush; 908. A second slider; 909. a clamping block; 10. a waste heat absorber; 11. a delivery pipe; 12. and (4) preheating a sleeve.

Detailed Description

The technical solutions in the embodiments of the present invention will be described clearly and completely with reference to the accompanying drawings in the embodiments of the present invention, and it is obvious that the described embodiments are only some embodiments of the present invention, not all embodiments. Based on the embodiments in the present invention, all other embodiments obtained by a person skilled in the art without creative work belong to the protection scope of the present invention.

Referring to fig. 1-4, a heat pipe type waste heat recovery device comprises a heat exchange mechanism 1, an air inlet mechanism and a waste heat recovery mechanism fixedly installed on the heat exchange mechanism 1, wherein the air inlet mechanism is fixedly installed on one side of the heat exchange mechanism 1;

waste heat recovery mechanism includes roof 7, heat pipe 8, adjusting part 9, waste heat absorber 10, conveyer pipe 11 and preheating sleeve 12, roof 7 fixed mounting is in heat exchange mechanism 1's top surface, heat pipe 8 fixed mounting is in the center department on roof 7 top surface, the top surface fixed mounting of roof 7 has four adjusting part 9, and four adjusting part 9 rings are established at heat pipe 8's lateral wall, four adjusting part 9's top all is connected with waste heat absorber 10's basal surface, waste heat absorber 10's top surface fixed mounting has conveyer pipe 11, the one end fixed mounting that waste heat absorber 10 was kept away from to conveyer pipe 11 has preheating sleeve 12, preheating sleeve 12 is fixed to be cup jointed on the mechanism that admits air.

Wherein, the adjusting component 9 comprises a hollow sleeve 901, a first telescopic rod 902, a sliding block 903, a threaded rod 904, a second threaded sleeve 905, a second telescopic rod 906, a third threaded sleeve 907, a second sliding block 908 and a clamping block 909, a sliding groove is vertically formed in the front end face of the hollow sleeve 901, the first telescopic rod 902 is movably sleeved at the bottom end of the hollow sleeve 901, the bottom end of the first telescopic rod 902 is connected with the top surface of the top plate 7, the sliding block 903 is fixedly arranged at the top of the front end face of the first telescopic rod 902, the sliding block 903 is positioned in the sliding groove, the top end of the first telescopic rod 902 is movably sleeved with the threaded rod 904, the outer surface of the threaded rod 904 is sleeved with the second threaded sleeve 905, the bottom surface of the second threaded sleeve 905 is contacted with the top surface of the first telescopic rod 902, the top end of the threaded rod 904 is movably sleeved with the second telescopic rod 906, the top end of the second telescopic rod 906 penetrates through the top surface of the hollow sleeve 901, the outer surface of the threaded sleeve 907 is sleeved with the third threaded sleeve 907, the top surface of the third thread bush 907 is in contact with the bottom surface of the second telescopic rod 906, the second sliding block 908 is movably sleeved on the front end face of the second telescopic rod 906, the second sliding block 908 is located in the sliding groove, the fixture block 909 is fixedly installed at the top end of the second telescopic rod 906, and the top surface of the fixture block 909 is connected with the bottom surface of the waste heat absorber 10, so that the adjustment of the distance between the waste heat absorber 10 and the top plate 7 is realized, and a better waste heat recovery effect is achieved.

Wherein, air inlet mechanism includes first intake pipe 2, magnetism subassembly 3, second intake pipe 4, 2 fixed mounting in one side of heat transfer mechanism 1 of first intake pipe, the one end fixed mounting that heat transfer mechanism 1 was kept away from to first intake pipe 2 has magnetism subassembly 3, one side fixed mounting that first intake pipe 2 was kept away from to magnetism subassembly 3 has second intake pipe 4, the fixed cover of surface of second intake pipe 4 has connect preheating sleeve 12, realized getting into the inside of heat transfer mechanism 1 with the air, better heat transfer effect has been reached.

Wherein, magnetism subassembly 3 is inhaled including anodal magnetism piece 301 and negative pole magnetism piece 302 of inhaling, and anodal magnetism piece 301 fixed mounting is in the one end of first intake pipe 2, and one side of piece 302 is inhaled with the one end of second intake pipe 4 to fixed negative pole magnetism, and anodal magnetism piece 301 is inhaled with negative pole magnetism and is inhaled piece 302 magnetism and be connected, has realized linking together first intake pipe 2 and second intake pipe 4, has reached better connection effect.

Wherein, heat exchange mechanism 1 includes heat exchanger casing 101, heat transfer fin 102, first adapter sleeve 103 and second adapter sleeve 104, and the top surface of heat exchanger casing 101 is connected with the basal surface of roof 7, and the inner chamber fixed mounting of heat exchanger casing 101 has a plurality of heat transfer fins 102, and one side fixed mounting of heat exchanger casing 101 has first adapter sleeve 103, and one side fixed mounting that first adapter sleeve 103 was kept away from to heat exchanger casing 101 has second adapter sleeve 104, has reached better heat transfer effect.

Wherein, one side that heat exchange mechanism 1 was kept away from to second adapter sleeve 104 is connected with first outlet duct 5, and the one end that heat exchange mechanism 1 was kept away from to first outlet duct 5 is connected with second outlet duct 6 through magnetism subassembly 3 of inhaling, is convenient for better fix first outlet duct 5 and second outlet duct 6 in one side of heat exchange mechanism 1.

When the device works, firstly, gas is introduced into the heat exchange mechanism 1 through the second gas inlet pipe 4 and the first gas inlet pipe 2, then heat exchange treatment is carried out through the heat exchange fins 102 in the heat exchange mechanism 1 and is discharged through the first gas outlet pipe 5 and the second gas outlet pipe 6, simultaneously, waste heat in the heat exchange mechanism 1 is sucked into the waste heat absorber 10 through the heat pipe 8 for waste heat utilization, then water in the preheating sleeve 12 is heated through the conveying pipe 11 by the waste heat, so that the gas entering the heat exchange mechanism 1 has better preheating effect, the heat in the heat exchange mechanism 1 can be effectively ensured to be recycled, when the first gas inlet pipe 2, the second gas inlet pipe 4, the first gas outlet pipe 5 and the second gas outlet pipe 6 are required to be disassembled, the positive magnetic suction block 301 and the negative magnetic suction block 302 are separated, when the distance between the waste heat absorber 10 and the top plate 7 is required to be adjusted, the second threaded sleeve 905 and the third threaded sleeve 907 on the threaded rod 904 are rotated anticlockwise, so that the distance between the waste heat absorber 10 and the top plate 7 is adjusted, and the waste heat recovery efficiency is further improved.

The above description is only a preferred embodiment of the present invention, and should not be taken as limiting the invention, and any modifications, equivalent replacements, improvements, etc. made within the spirit and principle of the present invention should be included in the protection scope of the present invention.

Claims (6)

1. A heat pipe type waste heat recovery device is characterized by comprising a heat exchange mechanism (1), an air inlet mechanism and a waste heat recovery mechanism arranged on the heat exchange mechanism (1), wherein the air inlet mechanism is arranged on one side of the heat exchange mechanism (1);

the waste heat recovery mechanism comprises a top plate (7), a heat pipe (8), a regulating component (9), a waste heat absorber (10), a conveying pipe (11) and a preheating sleeve (12), the top plate (7) is arranged on the top surface of the heat exchange mechanism (1), the heat pipe (8) is arranged at the center of the top surface of the top plate (7), the top surface of the top plate (7) is provided with four adjusting components (9), the four adjusting components (9) are annularly arranged on the outer side wall of the heat pipe (8), the top ends of the four adjusting components (9) are connected with the bottom surface of the waste heat absorber (10), the top surface of the waste heat absorber (10) is provided with the conveying pipe (11), the preheating sleeve (12) is installed at one end, far away from the waste heat absorber (10), of the conveying pipe (11), and the preheating sleeve (12) is installed on the air inlet mechanism.

2. The heat pipe type waste heat recovery device according to claim 1, wherein the adjusting assembly (9) comprises a hollow sleeve (901), a first telescopic rod (902), a sliding block (903), a threaded rod (904), a second threaded sleeve (905), a second telescopic rod (906), a third threaded sleeve (907), a second sliding block (908) and a clamping block (909), a sliding groove is vertically formed in the front end face of the hollow sleeve (901), the first telescopic rod (902) is sleeved at the bottom end of the hollow sleeve (901), the bottom end of the first telescopic rod (902) is connected with the top surface of the top plate (7), the sliding block (903) is mounted at the top of the front end face of the first telescopic rod (902), the sliding block (903) is located in the sliding groove, the threaded rod (904) is movably sleeved at the top end of the first telescopic rod (902), and the second threaded sleeve (905) is sleeved at the outer surface of the threaded rod (904), the bottom surface of the second threaded sleeve (905) is in contact with the top surface of the first telescopic rod (902), the top end of the threaded rod (904) is movably sleeved with the second telescopic rod (906), the top end of the second telescopic rod (906) penetrates through the top surface of the hollow sleeve (901), the outer surface of the threaded rod (904) is in threaded sleeve connection with the third threaded sleeve (907), the top surface of the third threaded sleeve (907) is in contact with the bottom surface of the second telescopic rod (906), the front end face of the second telescopic rod (906) is provided with the second sliding block (908), the second sliding block (908) is located in the sliding groove, the fixture block (909) is installed at the top end of the second telescopic rod (906), and the top surface of the fixture block (909) is connected with the bottom surface of the waste heat absorber (10).

3. A heat pipe type waste heat recovery device according to claim 1, wherein the air inlet mechanism comprises a first air inlet pipe (2), a magnetic attraction component (3) and a second air inlet pipe (4), the first air inlet pipe (2) is installed on one side of the heat exchange mechanism (1), the magnetic attraction component (3) is installed on one end of the first air inlet pipe (2) far away from the heat exchange mechanism (1), the second air inlet pipe (4) is installed on one side of the magnetic attraction component (3) far away from the first air inlet pipe (2), and the preheating sleeve (12) is sleeved on the outer surface of the second air inlet pipe (4).

4. A heat pipe type waste heat recovery device according to claim 3, wherein the magnetic attraction component (3) comprises a positive magnetic attraction block (301) and a negative magnetic attraction block (302), the positive magnetic attraction block (301) is installed at one end of the first air inlet pipe (2), one side of the negative magnetic attraction block (302) is connected with one end of the second air inlet pipe (4), and the positive magnetic attraction block (301) is magnetically attracted with the negative magnetic attraction block (302) and connected.

5. A heat pipe type waste heat recovery device according to claim 3, wherein the heat exchange mechanism (1) comprises a heat exchanger housing (101), heat exchange fins (102), a first connection sleeve (103) and a second connection sleeve (104), the top surface of the heat exchanger housing (101) is connected with the bottom surface of the top plate (7), the heat exchange fins (102) are installed in the inner cavity of the heat exchanger housing (101), the first connection sleeve (103) is installed on one side of the heat exchanger housing (101), and the second connection sleeve (104) is installed on one side of the heat exchanger housing (101) far away from the first connection sleeve (103).

6. A heat pipe type waste heat recovery device according to claim 5, wherein one side of the second connection sleeve (104) far away from the heat exchange mechanism (1) is connected with a first air outlet pipe (5), and one end of the first air outlet pipe (5) far away from the heat exchange mechanism (1) is connected with a second air outlet pipe (6) through the magnetic attraction component (3).

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