CN115682773A

CN115682773A - Heat exchanger with high heat exchange efficiency and monitoring function

Info

Publication number: CN115682773A
Application number: CN202211430232.1A
Authority: CN
Inventors: 杨新敬; 辛立民
Original assignee: Beijing Huaaixin Energy Saving Equipment Co ltd; Zhuozhou Ruitewei Mechanical Equipment Co ltd
Current assignee: Beijing Huaaixin Energy Saving Equipment Co ltd; Zhuozhou Ruitewei Mechanical Equipment Co ltd
Priority date: 2022-11-16
Filing date: 2022-11-16
Publication date: 2023-02-03
Anticipated expiration: 2042-11-16
Also published as: CN115682773B

Abstract

The invention discloses a heat exchanger with high heat exchange efficiency and a monitoring function, which relates to the field of heat exchangers and comprises a heat exchanger shell, a partition plate, a top cover and a plurality of baffle plates fixedly connected to two ends of the inner wall of the heat exchanger shell, wherein the plurality of baffle plates divide the interior of the heat exchanger shell into a plurality of cavities which are respectively named as a first cavity, a second cavity and a third cavity, and the partition plate is arranged in the first cavity; this heat exchanger with high heat exchange efficiency can monitor function, setting through separation mechanism, when rivers enter from first inlet tube, rivers can pass through separation mechanism, and be serpentine motion in the second cavity, thereby increase the working effect of heat exchanger, rivers can promote separation mechanism motion and separation mechanism and be in initial condition all the time when rivers get into from first outlet pipe, separation mechanism can polish the inside clean of assurance heat exchanger to the lateral wall of condenser pipe and second cavity inner wall, the velocity of flow of rivers can be controlled through the setting of current-limiting mechanism simultaneously.

Description

Heat exchanger with high heat exchange efficiency and monitoring function

Technical Field

The invention relates to a heat exchanger technology, in particular to a heat exchanger with high heat exchange efficiency and a monitoring function.

Background

The heat exchanger is a device for transferring part of heat of hot fluid to cold fluid, and is also called a heat exchanger. The heat exchanger plays an important role in chemical industry, petroleum industry, power industry, food industry and other industrial production, can be used as a heater, a cooler, a condenser, an evaporator, a reboiler and the like in chemical industry production, and is widely applied. According to the structure, the method can be divided into: floating head heat exchangers, fixed tube-plate heat exchangers, U-shaped tube-plate heat exchangers, and the like.

When using, can realize higher heat exchange efficiency for current heat exchanger, but the radiating tube inner wall can be attached to a large amount of precipitations in the heat exchanger, or the condensate quality descends etc. therefore influences heat exchange efficiency, consequently needs monitor heat exchange efficiency of heat exchanger, guarantees normal industrial production demand, needs carry out temperature measurement at equipment such as business turn over liquid mouth installation thermometer during the detection to this judges heat exchange efficiency. However, the existing heat exchanger only detects the heat exchange efficiency, and cannot clean the inner wall of the radiating pipe inside the heat exchanger.

Disclosure of Invention

The invention aims to provide a heat exchanger with high heat exchange efficiency and a monitoring function, so as to overcome the defects in the prior art.

In order to achieve the above purpose, the invention provides the following technical scheme: the heat exchanger with the function of monitoring the high heat exchange efficiency comprises a heat exchanger shell, a plurality of baffles, a top cover and a plurality of fixed connection baffles at two ends of the inner wall of the heat exchanger shell, wherein the baffles divide the interior of the heat exchanger shell into a plurality of cavities, the cavities are named as a first cavity, a second cavity and a third cavity respectively, the baffle is arranged in the first cavity, the first cavity is divided into an upper part and a lower part by the baffle, the first cavity is vertically and respectively provided with a second water inlet pipe and a second water outlet pipe in a penetrating manner, a condensing mechanism is arranged in the second cavity, the side wall of the second cavity is provided with a first water outlet pipe and a first water inlet pipe in a penetrating manner, the outer side walls of the first water outlet pipe and the first water inlet pipe are respectively provided with a first pipe sleeve and a second pipe sleeve in a sleeved manner, a current limiting mechanism is arranged in the second pipe sleeve, the side wall of the heat exchanger shell is provided with a temperature measuring mechanism, the two ends of the heat exchanger shell are respectively provided with a first flange and a third flange, the bottom of the top cover is provided with a second flange, and the heat exchanger shell and the top cover are fixedly connected with the second flange and the third flange.

Further, condensation mechanism includes a plurality of condenser pipes that run through the baffle and communicate first cavity and third cavity simultaneously, condenser pipe lateral wall sliding connection has a plurality of separation mechanisms, and all is provided with the baffler between the adjacent separation mechanism, the baffler bottom is provided with the breach, and is a plurality of separation mechanism runs through and is provided with same third dead lever, and has seted up a plurality of spouts on the third dead lever, and is a plurality of separation mechanism all is provided with the slider, and is a plurality of the slider slides respectively in the spout of difference.

Further, separation mechanism includes first baffle and second baffle, it is provided with a plurality of through holes to run through on the first baffle, and is a plurality of the condenser pipe runs through different through holes respectively, the sliding tray has been seted up on the first baffle, and the second baffle slides in the sliding tray, the standing groove has been seted up to the sliding tray bottom, fixedly connected with telescopic link in second baffle bottom, and telescopic link lateral wall cover are equipped with the spring, the spring both ends respectively with second baffle and first baffle fixed connection, through hole lateral wall, first baffle lateral wall and second baffle lateral wall all are provided with the material of polishing.

Furthermore, a water storage bin is arranged in the second baffle, the second baffle penetrates through a plurality of water outlet pipes, the inner walls of the water outlet pipes are arranged in a round table shape, water flow enters from the water outlet pipe flaring portion during heat exchange, a first water outlet groove and a second water outlet groove are formed in the two sides of each water outlet pipe respectively, and the bottoms of the first water outlet groove and the second water outlet groove are located on the same plane.

Further, current-limiting mechanism includes the connecting pipe with first inlet pipe inner wall connection, be provided with into water panel in the connecting pipe, and seted up a plurality of delivery ports on the panel of just intaking, be provided with the second dead lever on the panel of intaking, and second dead lever bottom rotates and is connected with the second flabellum, second flabellum and second dead lever top are established through the cover and are connected at the clockwork spring of second dead lever lateral wall, be provided with a plurality of gag lever posts that play limiting displacement to the second flabellum on the panel of intaking.

Further, the second fan blade is provided with a plurality of third baffles in an inclined mode, the inclination angle is an acute angle, the intersection line of the second fan blade and the third baffles is initially located on the water outlet axis, the second fan blade and the water inlet panel are attached to each other, and the second fan blade is located the water flow inflow direction.

Further, temperature measurement mechanism is including the electronic thermometer of first electronic thermometer and the electronic thermometer of second and external power supply system that run through first outlet pipe and first inlet tube respectively, heat exchanger casing lateral wall fixedly connected with fixed block, and rotate on the fixed block and be connected with the receiving coil, the winding has the stranded electric wire on the receiving coil, and stranded electric wire output end communicates with the electronic thermometer power input of first electronic thermometer power input end and second respectively, stranded electric wire input end and external power supply system intercommunication.

Further, the first water outlet pipe is positioned above the first water inlet pipe.

Compared with the prior art, the heat exchanger with the high heat exchange efficiency and the monitorable function has the advantages that through the arrangement of the blocking mechanism, when water flows in from the first water inlet pipe, the water flows can pass through the blocking mechanism and move in the second cavity in a snake shape, so that the working effect of the heat exchanger is improved, when the water flows in from the first water outlet pipe, the water flows can push the blocking mechanism to move, the blocking mechanism is always in an initial state, the blocking mechanism can polish the side wall of the condensation pipe and the inner wall of the second cavity to guarantee the cleanness of the interior of the heat exchanger, and meanwhile, the flow rate of the water flows can be controlled through the arrangement of the current limiting mechanism.

Drawings

In order to more clearly illustrate the embodiments of the present application or technical solutions in the prior art, the drawings needed to be used in the embodiments will be briefly described below, and it is obvious that the drawings in the following description are only some embodiments described in the present invention, and other drawings can be obtained by those skilled in the art according to the drawings.

FIG. 1 is a schematic diagram of an overall structure provided by an embodiment of the present invention;

FIG. 2 is a schematic side view of a left-right equiangular shaft according to an embodiment of the present invention;

FIG. 3 is a schematic structural diagram of a temperature measuring mechanism according to an embodiment of the present invention;

FIG. 4 is a schematic view of an initial state structure of a blocking mechanism according to an embodiment of the present invention;

FIG. 5 is a schematic structural diagram of a blocking mechanism according to an embodiment of the present invention;

FIG. 6 is an enlarged schematic view of the structure at A in FIG. 4;

fig. 7 is a schematic structural diagram of a flow limiting mechanism according to an embodiment of the present invention.

Description of reference numerals:

1. a heat exchanger housing; 2. a partition plate; 3. a first cavity; 4. a first flange plate; 5. a second flange plate; 6. a third flange plate; 7. a top cover; 8. a first water outlet pipe; 9. a first water inlet pipe; 10. a second water inlet pipe; 11. a second water outlet pipe; 12. a blocking mechanism; 121. a first baffle plate; 122. a second baffle; 123. a through hole; 124. a telescopic rod; 125. a spring; 126. a placement groove; 13. a condenser tube; 14. a first pipe sleeve; 15. a second pipe sleeve; 16. a first electric thermometer; 17. a second electric thermometer; 18. an electric wire; 19. a second water outlet groove; 20. a third fixing bar; 21. a fixed block; 22. winding a coil; 23. a chute; 24. a slider; 25. a barrier plate; 26. a flow limiting mechanism; 261. a second fixing bar; 262. a clockwork spring; 263. a second fan blade; 264. a third baffle plate; 265. a limiting rod; 266. a water outlet; 27. a water storage bin; 28. a water outlet pipe; 29. a first water outlet groove.

Detailed Description

In order to make the technical solutions of the present invention better understood, those skilled in the art will now describe the present invention in further detail with reference to the accompanying drawings.

Referring to fig. 1-7, a heat exchanger with high heat exchange efficiency and monitoring function includes a heat exchanger housing 1, a partition plate 2, a top cover 7 and a plurality of baffle plates fixedly connected to two ends of the inner wall of the heat exchanger housing 1, the plurality of baffle plates divide the interior of the heat exchanger housing 1 into a plurality of cavities, the plurality of cavities are respectively named as a first cavity 3, a second cavity and a third cavity, the partition plate 2 is disposed in the first cavity 3, the first cavity 3 is divided into an upper part and a lower part by the partition plate 2, a second water inlet pipe 10 and a second water outlet pipe 11 are respectively disposed in the first cavity 3 in a penetrating manner, a condensing mechanism is disposed in the second cavity, a first water outlet pipe 8 and a first water inlet pipe 9 are disposed in a penetrating manner on the side wall of the second cavity, wherein the second water inlet pipe 10 is filled with cooling water, the first water outlet pipe 8 is filled with hot water, the cooling water after absorbing heat flows out of the second water outlet pipe 11, the hot water after cooling flows out of the first water outlet pipe 8, so that the function of the heat exchanger can be realized, the outer side walls of the first water outlet pipe 8 and the first water inlet pipe 9 are respectively sleeved with the first pipe sleeve 14 and the second pipe sleeve 15, the current limiting mechanism 26 is arranged in the second pipe sleeve 15, the side wall of the heat exchanger shell 1 is provided with the temperature measuring mechanism, the two ends of the heat exchanger shell 1 are respectively provided with the first flange plate 4 and the third flange plate 6, so that the heat exchanger shell 1 can be fixedly connected to a place needing the heat exchanger through the first flange plate 4, the bottom of the top cover 7 is provided with the second flange plate 5, the heat exchanger shell 1 and the top cover 7 are fixedly connected through the second flange plate 5 and the third flange plate 6, and the stable connection of the heat exchanger shell 1 and the top cover 7 can be ensured through the arrangement.

The condensation mechanism comprises a plurality of condensation pipes 13 which penetrate through the baffle plate and simultaneously communicate the first cavity 3 with the third cavity, when cooling water is introduced into the second water inlet pipe 10, water flow can enter the third cavity through the condensation pipes 13 communicated with the upper portion of the first cavity 3, along with the continuous increase of water in the third cavity, when the third cavity is filled with water, the cooling water continues to be introduced, the cooling water can enter the lower portion of the first cavity 3 along with the condensation pipes 13 communicated with the lower portion of the first cavity 3 and is discharged through the second water outlet pipe 11, the side walls of the condensation pipes 13 are slidably connected with a plurality of separation mechanisms 12, a separation plate 25 is arranged between every two adjacent separation mechanisms 12, a gap is formed in the bottom of the separation plate 25, the separation mechanisms 12 penetrate through the same third fixing rod 20, a plurality of sliding grooves 23 are formed in the third fixing rod 20, sliding blocks 24 are arranged on the separation mechanisms 12, the sliding blocks 24 respectively slide in different sliding grooves 23, and when the purpose is achieved, the separation mechanisms 12 can slide on the third fixing rod 20 through the sliding grooves 23 and the sliding blocks 24.

The blocking mechanism 12 comprises a first baffle plate 121 and a second baffle plate 122, a plurality of through holes 123 are arranged on the first baffle plate 121 in a penetrating manner, a plurality of condenser tubes 13 are respectively arranged on the through holes 123 in a penetrating manner, a sliding groove is arranged on the first baffle plate 121, the second baffle plate 122 slides in the sliding groove, a placing groove 126 is arranged at the bottom of the sliding groove, an expansion link 124 is fixedly connected to the bottom of the second baffle plate 122, a spring 125 is sleeved on the side wall of the expansion link 124, and two ends of the spring 125 are respectively fixedly connected with the second baffle plate 122 and the first baffle plate 121, so that when the baffle mechanism is in an initial state, as shown in figure 4, when the second baffle plate 122 is under pressure, the second baffle plate 122 can move downwards, referring to as shown in fig. 5, when a plurality of separation mechanisms 12 are all in the state as shown in fig. 5, and a plurality of second baffles 122 are arranged in a crossed manner, the purpose of setting up like this is when second baffle 122 receives pressure, water flow is snakelike motion in the second cavity, increase the contact area with condenser pipe 13, and improve the work efficiency of the heat exchanger, the through hole 123 side wall, first baffle 121 side wall and second baffle 122 side wall are all provided with the material of polishing, the purpose of setting up like this is, when being in the initial state, and when separation mechanisms 12 move, separation mechanisms 12 can polish the side wall of condenser pipe 13 and the inner wall of the second cavity to ensure the cleanness inside the heat exchanger.

The water storage bin 27 is arranged in the second baffle plate 122, the second baffle plate 122 is provided with a plurality of water outlet pipes 28 in a penetrating way, the inner walls of the plurality of water outlet pipes 28 are arranged in a round table shape, and water flow enters from the flaring part of the water outlet pipe 28 during heat exchange, the purpose of the arrangement is that when the water flow impacts the second baffle plate 122, the water flow flows into the water storage bin 27 through the water outlet when in the water outlet pipe 28, when the water enters the water storage bin 27, the gravity of the second baffle plate 122 is increased, so that the second baffle plate 122 slides into the sliding groove, when the second baffle plate 122 slides downwards a little, the bottom of the first water outlet groove 29 and the bottom of the second water outlet groove 19 are blocked by the sliding groove, as the water in the water storage bin 27 is continuously increased, and the pressure on the top of the second baffle plate 122 is continuously increased, the second baffle plate 122 can completely slide into the sliding groove, at this time, the water flow can pass through the blocking mechanism 12, the second cavity moves in a serpentine shape, the two sides of the water outlet pipe 28 are respectively provided with a first water outlet groove 29 and a second water outlet groove 19, and the bottoms of the first water outlet groove 29 and the second water outlet groove 19 are in the same plane, so that the purpose is that when the water flow stops moving, the impact force on the top of the second baffle 122 is reduced, the spring 125 can push the second baffle 122 to move upwards, when the second baffle 122 moves upwards a little, the water in the water storage bin 27 can flow out, when the water in the water storage bin 27 flows out, the gravity of the second baffle 122 is reduced, the spring 125 can push the second baffle 122 to continuously move upwards until the water flow in the water storage bin 27 is empty, and meanwhile, when the water flow enters from the second water outlet pipe 8, because the water outlet of the water flow 28 is small, the water flow cannot flow through the second water outlet pipe 8, the water flow can push the blocking mechanism 12 to move and the blocking mechanism 12 is constantly in an initial state along with the water flow injection, the blocking mechanism 12 can polish the side wall of the condensation pipe 13 and the inner wall of the second cavity to ensure the cleanness of the inside of the heat exchanger.

Current-limiting mechanism 26 includes the connecting pipe with first inlet tube 9 inner wall connection, be provided with the panel of intaking in the connecting pipe, and intake and seted up a plurality of delivery ports 266 on the panel, be provided with second dead lever 261 on the panel of intaking, and second dead lever 261 bottom is rotated and is connected with second flabellum 263, second flabellum 263 and second dead lever 261 top are connected through the clockwork spring 262 that the cover was established at second dead lever 261 lateral wall, the setting that adopts clockwork spring 262 is for driving second flabellum 263 to deflect under clockwork spring 262's effect, rather than driving second flabellum 263 and taking place to rotate, it plays limiting displacement's gag lever post 265 to second flabellum 263 to be provided with a plurality ofly on the panel of intaking. This is done to avoid the situation where the water outlet 266 is completely blocked by the second blade 263 when the water flow is too high.

The third baffles 264 are obliquely arranged on the second blade 263, the inclination angle is an acute angle, the intersection line of the second blade 263 and the third baffles 264 is initially located on the axis of the water outlet 266, the purpose of the arrangement is that when water flows through the second blade 263, the intersection line of the second blade 263 and the third baffles 264 is driven to rotate under the impact of the water flow, the intersection line of the second blade 263 and the third baffles 264 is located on the axis of the water outlet 266, wherein as shown in fig. 4, the initial intersection line of the second blade 263 and the third baffles 264 is located on the axis of the water outlet 266 due to the acting force of the spring 262 on the second blade 263 in the initial state, the acting force changes when the third baffles 264 are impacted by the water flow, the second blade 263 deflects, the second blade 263 and the water inlet panel are attached to each other, and the second blade 263 is located in the water flow inflow direction, so that when the second blade 263 rotates, the opening position between the second blade 263 and the water outlet 266 may be changed, when the third baffles 264 receives too small force to rotate relative to the second blade 262, the second blade 262 may be smaller than the second blade 263, when the water flow rate of the water flow is increased, and when the water flow is increased, the water flow rate is increased by the water flow, the rotating voltage of the second blade 263, thereby increasing the water flow of the water flow rate of the water flow is increased.

The temperature measuring mechanism comprises a first electric thermometer 16 and a second electric thermometer 17 which respectively penetrate through a first water outlet pipe 8 and a first water inlet pipe 9, the temperature of water flow of the first water outlet pipe 8 and the first water inlet pipe 9 can be measured through the first electric thermometer 16 and the second electric thermometer 17 in the setting mode, the heat exchange efficiency of the heat exchanger can be calculated, a fixing block 21 is fixedly connected to the side wall of the heat exchanger shell 1, a receiving coil 22 is connected to the fixing block 21 in a rotating mode, an electric wire 18 is wound on the receiving coil 22, winding and unwinding of the electric wire 18 can be achieved through rotating the receiving coil 22 in the setting mode, the portability of the device is prevented from being influenced by overlong length of the electric wire 18, the output end of the multistrand electric wire 18 is communicated with the power input end of the first electric thermometer 16 and the power input end of the second electric thermometer 17, the input end of the multistrand electric wire 18 is communicated with an external power supply system, the first electric thermometer 16 and the second electric thermometer 17 are powered through the external power supply system, the heat exchanger can be read, and the heat exchange efficiency of the heat exchanger can be calculated, and the monitoring of the heat exchange efficiency is achieved.

The first water outlet pipe 8 is positioned above the first water inlet pipe 9, and the first water inlet pipe 9 is positioned below the first water outlet pipe 8 so as to ensure that the water flow does not exchange heat sufficiently in the second cavity due to the influence of gravity when moving in the second cavity.

While certain exemplary embodiments of the present invention have been described above by way of illustration only, it will be apparent to those of ordinary skill in the art that the described embodiments may be modified in various different ways without departing from the spirit and scope of the invention. Accordingly, the drawings and description are illustrative in nature and should not be construed as limiting the scope of the invention.

Claims

1. But heat exchanger with high heat exchange efficiency monitoring function, including heat exchanger casing (1), baffle (2), top cap (7) and a plurality of fixed connection at the baffle at heat exchanger casing (1) inner wall both ends, its characterized in that, a plurality of the baffle divides heat exchanger casing (1) inside into a plurality of cavitys, and a plurality of cavitys are named first cavity (3), second cavity and third cavity respectively, be provided with baffle (2) in first cavity (3), baffle (2) divide into two parts from top to bottom with first cavity (3), first cavity (3) are run through respectively from top to bottom and are provided with second inlet tube (10) and second outlet pipe (11), be provided with condensation mechanism in the second cavity, the second cavity lateral wall runs through and is provided with first outlet pipe (8) and first inlet tube (9), first outlet pipe (8) and first inlet tube (9) lateral wall are equipped with first pipe box (14) and second pipe box (15) respectively, be provided with current-limiting mechanism (26) in the second pipe box (15), casing (1) lateral wall is provided with temperature measurement mechanism, heat exchanger casing (1) both ends are provided with first ring flange (4) and third ring flange (6) and heat exchanger casing (7) and second ring flange (5) are provided with through the top cap (5) respectively, and third ring flange (7) and second ring flange (5) and first ring flange (6) and second ring flange (5) are provided with the heat exchanger casing (5) bottom and the top cap (5) respectively, and the heat exchanger casing (3) and the top cap (3) is provided with the second ring (7) and the second ring flange (3) is provided with the top cap (3) and the second ring flange (7) is provided with the top cap (3) respectively And (4) fixedly connecting.

2. The heat exchanger with the function of monitoring the high heat exchange efficiency according to claim 1, wherein the condensing mechanism comprises a plurality of condensing pipes (13) penetrating through the baffle plate and simultaneously communicating the first cavity (3) and the third cavity, a plurality of blocking mechanisms (12) are slidably connected to the side wall of each condensing pipe (13), a blocking plate (25) is arranged between every two adjacent blocking mechanisms (12), a gap is arranged at the bottom of each blocking plate (25), a plurality of blocking mechanisms (12) are penetrated and provided with a same third fixing rod (20), a plurality of sliding grooves (23) are formed in each third fixing rod (20), a plurality of sliding blocks (24) are arranged in each blocking mechanism (12), and the plurality of sliding blocks (24) respectively slide in different sliding grooves (23).

3. The heat exchanger with the high heat exchange efficiency and the monitorable function according to claim 2, wherein the blocking mechanism (12) comprises a first baffle plate (121) and a second baffle plate (122), a plurality of through holes (123) are formed in the first baffle plate (121) in a penetrating manner, the plurality of condenser tubes (13) are respectively formed in the through holes (123), a sliding groove is formed in the first baffle plate (121), the second baffle plate (122) slides in the sliding groove, a placing groove (126) is formed in the bottom of the sliding groove, a telescopic rod (124) is fixedly connected to the bottom of the second baffle plate (122), a spring (125) is sleeved on the side wall of the telescopic rod (124), two ends of the spring (125) are respectively and fixedly connected with the second baffle plate (122) and the first baffle plate (121), and grinding materials are arranged on the side walls of the through holes (123), the first baffle plate (121) and the second baffle plate (122).

4. The heat exchanger with the high heat exchange efficiency and the monitorable function according to claim 3 is characterized in that a water storage bin (27) is formed in the second baffle plate (122), a plurality of water outlet pipes (28) are arranged in the second baffle plate (122) in a penetrating manner, inner walls of the plurality of water outlet pipes (28) are arranged in a circular truncated cone shape, water flows enter from flaring positions of the water outlet pipes (28) during heat exchange, a first water outlet groove (29) and a second water outlet groove (19) are formed in two sides of each water outlet pipe (28), and bottoms of the first water outlet groove (29) and the second water outlet groove (19) are located on the same plane.

5. The heat exchanger with high heat exchange efficiency and monitoring function according to claim 4, wherein the flow limiting mechanism (26) comprises a connecting pipe connected with the inner wall of the first water inlet pipe (9), a water inlet panel is arranged in the connecting pipe, a plurality of water outlets (266) are formed in the water inlet panel, a second fixing rod (261) is arranged on the water inlet panel, a second blade (263) is rotatably connected to the bottom of the second fixing rod (261), the tops of the second blade (263) and the second fixing rod (261) are connected through a spiral spring (262) sleeved on the side wall of the second fixing rod (261), and a plurality of limiting rods (265) for limiting the second blade (263) are arranged on the water inlet panel.

6. The heat exchanger with high heat exchange efficiency and monitoring function as claimed in claim 5, wherein the second blade (263) is provided with a plurality of third baffles (264) in an inclined manner, the inclination angle is an acute angle, the intersection line of the second blade (263) and the third baffles (264) is initially located on the axis of the water outlet (266), the second blade (263) and the water inlet panel are attached to each other, and the second blade (263) is located in the water inflow direction.

7. The heat exchanger with the high heat exchange efficiency and the monitorable function is characterized in that the temperature measuring mechanism comprises a first electric thermometer (16) and a second electric thermometer (17) which respectively penetrate through a first water outlet pipe (8) and a first water inlet pipe (9) and an external power supply system, a fixing block (21) is fixedly connected to the side wall of the heat exchanger shell (1), a receiving coil (22) is rotatably connected to the fixing block (21), a plurality of wires (18) are wound on the receiving coil (22), the output ends of the plurality of wires (18) are respectively communicated with the power input end of the first electric thermometer (16) and the power input end of the second electric thermometer (17), and the input ends of the plurality of wires (18) are communicated with the external power supply system.

8. The heat exchanger with high heat exchange efficiency monitorable function according to claim 7 and characterized in that the first outlet conduit (8) is located above the first inlet conduit (9).