CN219736092U - Heat exchanger with high heat exchange efficiency - Google Patents

Abstract

The utility model provides a heat exchanger with high heat exchange efficiency, which relates to the technical field of chemical equipment and comprises heat exchanger brackets, wherein a top sealing plate and an installation bottom plate are respectively arranged between the heat exchanger brackets, a heat exchange component is arranged between the top sealing plate and the installation bottom plate, auxiliary heat exchange pipes are arranged at equal intervals in the vertical directions of the edges of the top sealing plate and the installation bottom plate, longitudinal support rods are arranged at the corner positions of the top sealing plate and the installation bottom plate, heat exchange pipes are vertically embedded at the edges of the top sealing plate, a feeding port and a discharging pipe are respectively arranged at two sides of the installation bottom plate, heat is transferred by adopting a heat exchange main plate, heat is dissipated through a heat exchange cavity between the heat exchange main plates, meanwhile, heat is impacted through heat exchange convex blocks in the heat exchange cavity, and heat is further conducted through heat exchange ribs, so that heat is dissipated in a penetrating way, grooves are arranged on the surfaces of the heat exchange ribs, the heat is conducted through the grooves, the heat flow is further accelerated, and the heat exchange efficiency is improved.

Description

Heat exchanger with high heat exchange efficiency

Technical Field

The utility model relates to the technical field of chemical equipment, in particular to a heat exchanger with high heat exchange efficiency.

Background

According to a heat exchanger that circulated formula can improve heat exchange efficiency of chinese patent No. CN115406270a, it includes the cooling shell and sets up the heat transfer device in the cooling shell is inside, holds the liquid that carries out the cooling to the heat transfer device in the cooling shell, and the inside of cooling shell is provided with the water pump that drives the flow with liquid in the cooling shell, and the position that the inside of cooling shell is close to the bottom side is established to the cooling chamber, and the upside of cooling chamber is provided with the heat transfer chamber, and one side of cooling chamber is provided with the drainage chamber. According to the utility model, the liquid in the cooling cavity is pushed into the heat exchange cavity by the water pump, flows into the drainage cavity from the heat exchange cavity, and is absorbed by the water pump, so that the liquid circulates in the cooling shell, and meanwhile, after the liquid enters the heat exchange cavity and the drainage cavity, the heat in the liquid can be outwards diffused, so that the heat of the liquid is reduced, the heat absorption effect of the device is improved, and the heat exchange effect of the device is improved.

Among the above-mentioned patent content and prior art products, all heat exchangers mostly just adopt simple plate heat exchanger, and the structure of heat transfer board does not design, and heat exchange efficiency promotes comparatively difficultly, is difficult to realize higher heat exchange efficiency.

Disclosure of Invention

The utility model aims to solve the defects in the prior art, and provides a heat exchanger with high heat exchange efficiency.

In order to achieve the above purpose, the present utility model adopts the following technical scheme: the utility model provides a high heat exchange efficiency's heat exchanger, includes the heat exchanger support, be equipped with top shrouding and mounting plate about between the heat exchanger support respectively, be equipped with heat exchange assembly between top shrouding and the mounting plate, the equidistant auxiliary heat exchange tube that is equipped with in top shrouding and mounting plate's edge vertical direction, top shrouding and mounting plate's corner position is equipped with vertical vaulting pole, the vertical gomphosis in top shrouding edge has heat exchange tube, mounting plate's both sides are equipped with feed port and ejection of compact pipeline respectively.

Preferably, the heat exchanger support is bolted with a connecting cross rod in the horizontal direction, and a mounting hinge is arranged between the heat exchanger support and the heat exchange assembly on one side.

Preferably, the heat exchange assembly comprises heat exchange main boards evenly distributed in the middle of top sealing boards and mounting bottom boards, heat exchange ribs and heat exchange convex blocks are respectively arranged on the surfaces of adjacent heat exchange main boards, a heat exchange cavity is formed between the adjacent two heat exchange main boards, and positioning notches are formed at the end parts of the heat exchange main boards.

Preferably, the heat exchange pipeline and the auxiliary heat exchange pipe are connected with the feeding port and the discharging pipeline, and the feeding port and the discharging pipeline are independently communicated with the heat exchange pipeline and the auxiliary heat exchange pipe.

Preferably, the mounting bottom plate and the top sealing plate are provided with grooves at the contact positions of the heat exchange assembly, the inner cavities of the mounting bottom plate and the top sealing plate are uniformly provided with through holes, and the side surfaces of the mounting bottom plate and the top sealing plate are mutually embedded with the heat exchanger bracket.

Preferably, the mounting hinge is connected with two sections of heat exchanger brackets at one side, and the middle part of the mounting hinge is embedded in a groove at the side surface of the top sealing plate.

Preferably, the heat exchange convex blocks are uniformly distributed on the bottom surface of the heat exchange main board, and the heat exchange convex blocks are arranged on the surface of the heat exchange main board in a diamond manner.

Preferably, the heat exchange ribs are arranged on the top surface of the heat exchange main board in a streamline shape, and single-line spiral grooves are arranged on the surface of the heat exchange ribs at equal intervals.

Advantageous effects

According to the heat exchange device, heat is transferred by the heat exchange main boards, the heat is dissipated through the heat exchange cavities between the heat exchange main boards, meanwhile, the heat flow in the heat exchange cavities is impacted through the heat exchange convex blocks, and the heat flow is further guided through the heat exchange ribs, so that the heat is dissipated in a penetrating manner, meanwhile, the grooves are formed in the surfaces of the heat exchange ribs, the heat flow can be guided through the grooves and guided through the spiral grooves, so that the flow speed of the heat flow is further accelerated, and the heat exchange efficiency is improved;

according to the utility model, the heat exchange convex blocks are adopted, when heat flow upwards escapes and impacts the heat exchange convex blocks, the heat flow is impacted and diverged, the heat flow is homogenized, the heat exchange effect is further improved, and the heat exchange efficiency is improved.

Drawings

FIG. 1 is a side elevational view of the present utility model;

FIG. 2 is a main block diagram of the present utility model;

FIG. 3 is a front view of the present utility model;

FIG. 4 is an internal block diagram of the present utility model;

fig. 5 is an enlarged view of a portion of fig. 4 a in accordance with the present utility model.

Legend description:

1. a heat exchanger support; 2. connecting the cross bars; 3. installing a hinge; 4. a feed port; 5. a heat exchange assembly; 501. a heat exchange lug; 502. positioning the notch; 503. heat exchange ribs; 504. a heat exchange main board; 505. a heat exchange cavity; 6. a mounting base plate; 7. a longitudinal brace; 8. a top closure plate; 9. a heat exchange pipeline; 10. an auxiliary heat exchange tube; 11. and a discharging pipeline.

Detailed Description

In order that the manner in which the above recited features, objects and advantages of the present utility model are obtained, a more particular description of the utility model will be rendered by reference to specific embodiments thereof which are illustrated in the appended drawings. Based on the examples in the embodiments, those skilled in the art can obtain other examples without making any inventive effort, which fall within the scope of the utility model.

Specific embodiments of the present utility model are described below with reference to the accompanying drawings.

First embodiment:

referring to fig. 1-5, a heat exchanger with high heat exchange efficiency comprises a heat exchanger bracket 1, a top sealing plate 8 and a mounting bottom plate 6 are respectively arranged between the heat exchanger bracket 1, a heat exchange component 5 is arranged between the top sealing plate 8 and the mounting bottom plate 6, grooves are respectively arranged at the contact positions of the heat exchange component 5 on the mounting bottom plate 6 and the top sealing plate 8, through holes are uniformly arranged in inner cavities of the mounting bottom plate 6 and the top sealing plate 8, the side surfaces of the mounting bottom plate 6 and the top sealing plate 8 are mutually embedded with the heat exchanger bracket 1, auxiliary heat exchange pipes 10 are arranged at equal intervals in the vertical direction of the edges of the top sealing plate 8 and the mounting bottom plate 6, longitudinal supporting rods 7 are arranged at the corner positions of the top sealing plate 8 and the mounting bottom plate 6, heat exchange pipes 9 are vertically embedded at the edges of the top sealing plate 8, the heat exchange pipes 9 and the auxiliary heat exchange pipes 10 are mutually connected with a feed port 4 and a discharge pipe 11, the feed port 4, the discharge pipeline 11, the heat exchange pipeline 9 and the auxiliary heat exchange pipe 10 are independently communicated, the feed port 4 and the discharge pipeline 11 are respectively arranged at two sides of the installation base plate 6, the connecting cross rod 2 is connected in a bolt manner in the horizontal direction of the heat exchanger support 1, the installation hinge 3 is arranged between the heat exchanger support 1 and the heat exchange component 5 at one side, the installation hinge 3 is connected with the two sections of the heat exchanger support 1 at one side, the middle part of the installation hinge 3 is embedded in a groove at the side surface of the top sealing plate 8, the heat exchange component 5 comprises heat exchange main plates 504 uniformly distributed between the top sealing plate 8 and the installation base plate 6, the surfaces of adjacent heat exchange main plates 504 are respectively provided with heat exchange ribs 503 and heat exchange lugs 501, the heat exchange lugs 501 are uniformly distributed on the bottom surface of the heat exchange main plates 504, the heat exchange lugs 501 are arranged in diamond manner on the surface of the heat exchange main plates 504, the heat exchange ribs 503 are in streamline form on the top surface of the heat exchange main plates 504, and single-line spiral grooves are formed in the surface of the heat exchange rib 503 at equal intervals, a heat exchange cavity 505 is formed between two adjacent heat exchange mainboards 504, and positioning notches 502 are formed at the end parts of the heat exchange mainboards 504.

In this embodiment, the specific working scheme is as follows: during operation, condensed liquid enters through the feed port 4, the pipeline penetrates through the heat exchange assembly 5 and is uniformly distributed in the heat exchange assembly 5, the liquid is finally output through the discharge pipeline 11, during heat exchange operation, heat is transmitted through the built-in pipeline and is emitted through the heat exchange cavity 505 between the heat exchange mainboards 504, meanwhile, heat flows in the heat exchange cavity 505 are impacted through the heat exchange convex blocks 501, heat flows are further guided through the heat exchange ribs 503, heat flows are emitted through the heat exchange ribs 503, grooves are formed in the surfaces of the heat exchange ribs 503, the heat flows can be guided through the grooves, the spiral grooves are guided, accordingly, the flow speed of the heat flows is further accelerated, the heat exchange efficiency is improved, and the heat flows are impacted and emitted when the heat flows upwards escape and impact the heat exchange convex blocks 501, so that the heat exchange effect is further improved.

Specific embodiment II:

based on the basic content of the first embodiment, in this embodiment, further technical schemes can be adjusted according to actual working conditions, and the heat exchanger support 1 and the connecting cross rod 2 with different shapes and sizes are installed, so that structural adjustment is performed according to the actual working conditions, and therefore different shapes and structures can be adapted, and meanwhile, different structures are adopted, and the technical structural content of the heat exchange component 5 in the main body of the scheme is not affected.

Third embodiment:

based on the basic content of the first embodiment, in this embodiment, further technical solutions may replace the heat exchange bump 501 with a structure with a different shape, and adopt a conical structure, and may guide the hot air flow to the surface of the heat exchange motherboard 504, and adopt a planar structure, and may homogenize the hot air flow, and then accelerate the flow of the hot air flow through the grooves on the surface of the heat exchange ribs 503.

To sum up:

1. the heat exchange main boards 504 are adopted to transfer heat, the heat is dissipated through the heat exchange cavities 505 between the heat exchange main boards 504, meanwhile, the heat flow in the heat exchange cavities 505 is impacted through the heat exchange convex blocks 501, and the heat flow is further guided through the heat exchange ribs 503, so that the heat is dissipated in a penetrating manner, meanwhile, grooves are formed in the surfaces of the heat exchange ribs 503, the heat flow can be guided through the grooves, and the spiral grooves are guided, so that the flow speed of the heat flow is further accelerated, and the heat exchange efficiency is improved;

2. by adopting the heat exchange convex block 501, when heat flow upwards escapes and impacts the heat exchange convex block 501, the heat flow is impacted and diverged, the heat flow is homogenized, the heat exchange effect is further improved, and the heat exchange efficiency is improved.

In the present utility model, unless expressly stated or limited otherwise, a first feature "above" or "below" a second feature may include both the first and second features being in direct contact, as well as the first and second features not being in direct contact but being in contact with each other through additional features therebetween. Moreover, a first feature being "above," "over" and "on" a second feature includes the first feature being directly above and obliquely above the second feature, or simply indicating that the first feature is higher in level than the second feature. The first feature being "under", "below" and "beneath" the second feature includes the first feature being directly under and obliquely below the second feature, or simply means that the first feature is less level than the second feature.

The foregoing has shown and described the basic principles, principal features and advantages of the utility model. It will be understood by those skilled in the art that the present utility model is not limited to the above-described embodiments, and that the above-described embodiments and descriptions are only preferred embodiments of the present utility model, and are not intended to limit the utility model, and that various changes and modifications may be made therein without departing from the spirit and scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims (8)

1. The utility model provides a high heat exchange efficiency's heat exchanger, includes heat exchanger support (1), its characterized in that: the heat exchanger comprises a heat exchanger support (1), wherein a top sealing plate (8) and a mounting bottom plate (6) are arranged between the heat exchanger support (1) up and down, a heat exchange assembly (5) is arranged between the top sealing plate (8) and the mounting bottom plate (6), auxiliary heat exchange pipes (10) are arranged at equal intervals in the vertical direction of the edges of the top sealing plate (8) and the mounting bottom plate (6), longitudinal supporting rods (7) are arranged at the corner positions of the top sealing plate (8) and the mounting bottom plate (6), heat exchange pipelines (9) are vertically embedded at the edges of the top sealing plate (8), a feeding port (4) and a discharging pipeline (11) are respectively arranged on two sides of the mounting bottom plate (6), the heat exchange assembly (5) comprises heat exchange main boards (504) which are evenly distributed in the middle of the top sealing plate (8) and the mounting bottom plate (6), heat exchange ribs (503) and heat exchange bumps (501) are respectively arranged on the surfaces of the heat exchange main boards (504), and two adjacent heat exchange main boards (504) form a heat exchange cavity (505).

2. A high heat exchange efficiency heat exchanger according to claim 1, wherein: the heat exchanger support (1) is horizontally bolted with a connecting cross rod (2), and a mounting hinge (3) is arranged between the heat exchanger support (1) and the heat exchange assembly (5) on one side.

3. A high heat exchange efficiency heat exchanger according to claim 1, wherein: and positioning notches (502) are formed in the end parts of the heat exchange main boards (504).

4. A high heat exchange efficiency heat exchanger according to claim 1, wherein: the heat exchange pipeline (9) and the auxiliary heat exchange pipe (10) are connected with the feeding port (4) and the discharging pipeline (11), and the feeding port (4), the discharging pipeline (11) and the heat exchange pipeline (9) and the auxiliary heat exchange pipe (10) are independently communicated.

5. A high heat exchange efficiency heat exchanger according to claim 1, wherein: the mounting bottom plate (6) and the top sealing plate (8) are both provided with grooves at the contact positions of the heat exchange assembly (5), through holes are uniformly formed in the inner cavities of the mounting bottom plate (6) and the top sealing plate (8), and the side surfaces of the mounting bottom plate (6) and the top sealing plate (8) are mutually embedded with the heat exchanger bracket (1).

6. A high heat exchange efficiency heat exchanger according to claim 2, wherein: the mounting hinge (3) is connected with the two sections of heat exchanger brackets (1) at one side, and the middle part of the mounting hinge (3) is embedded in the groove at the side surface of the top sealing plate (8).

7. A high heat exchange efficiency heat exchanger according to claim 3, wherein: the heat exchange bumps (501) are uniformly distributed on the bottom surface of the heat exchange main board (504), and the heat exchange bumps (501) are arranged on the surface of the heat exchange main board (504) in a diamond shape.

8. A high heat exchange efficiency heat exchanger according to claim 3, wherein: the heat exchange ribs (503) are arranged on the top surface of the heat exchange main board (504) in a streamline shape, and single-line spiral grooves are arranged on the surface of the heat exchange ribs (503) at equal intervals.