CN215638993U

CN215638993U - Fin type condenser with supporting structure

Info

Publication number: CN215638993U
Application number: CN202123253056.2U
Authority: CN
Inventors: 吴若珍
Original assignee: Hangzhou Zhuoyue Heat Exchange Equipment Co ltd
Current assignee: Hangzhou Zhuoyue Heat Exchange Equipment Co ltd
Priority date: 2021-12-23
Filing date: 2021-12-23
Publication date: 2022-01-25
Anticipated expiration: 2031-12-23

Abstract

The utility model provides a finned condenser with a supporting structure, which relates to the technical field of finned condensers and comprises a supporting pad and a condensing mechanism, wherein the top side of the supporting pad supports a supporting assembly, the inner side of the supporting assembly is provided with a shell assembly, the outer side of the supporting assembly supports the condensing mechanism, the condensing mechanism comprises a pipeline node, a straight pipe, a hollow copper pipe, a copper wire armor, a fin group and a water outlet pipe, and the straight pipe is arranged below the pipeline node; the utility model mainly utilizes a plurality of groups of condenser pipes distributed in an array to match with nodes at two ends to uniformly convey water, so that the temperature difference of a radiating pipeline is reduced, and because a plurality of copper wire assemblies are wound and coated on the outer side of the pipeline, the radiating efficiency is improved, the strength and toughness of the assemblies are increased, the equipment cannot be burst and other accidents in long-time use.

Description

Fin type condenser with supporting structure

Technical Field

The utility model relates to the technical field of finned condensers, in particular to a finned condenser with a supporting structure.

Background

The finned condenser is also called a finned radiator, and is a heat exchange device which is most widely used in a gas and liquid heat exchanger, the finned condenser achieves the purpose of enhancing heat transfer by additionally arranging fins on a common base pipe, and the base pipe can be made of a steel pipe; a stainless steel tube; copper tubes, etc., and the fins may be steel strips; stainless steel belts, copper belts, aluminum belts, and the like.

In the use process of the existing finned condenser, the problems that the cooling effect of equipment cannot be achieved and great loss is caused due to the fact that a condensing pipeline bursts due to the fact that the temperature is too high and the temperature difference is large when the existing finned condenser is used for a long time are solved.

SUMMERY OF THE UTILITY MODEL

In order to solve the problems, the utility model provides a finned condenser with a supporting structure, which mainly utilizes a plurality of groups of condenser pipes distributed in an array manner to be matched with nodes at two ends for uniform conveying of water, so that the temperature difference of a radiating pipeline is reduced, and a plurality of copper wire assemblies are wound and coated on the outer side of the pipeline, so that the radiating efficiency is improved, the strength and the toughness of the assemblies are increased, the equipment cannot be burst and other accidents in long-time use, compared with the prior art, the finned condenser with the supporting structure is not easy to cause equipment fault and water leakage, and the service life of the equipment is prolonged.

In order to realize the purpose of the utility model, the utility model is realized by the following technical scheme: a finned condenser with a supporting structure comprises a supporting pad and a condensing mechanism, wherein a supporting assembly is supported on the top side of the supporting pad, a shell assembly is arranged on the inner side of the supporting assembly, and the condensing mechanism is supported on the outer side of the supporting assembly;

the condensation mechanism comprises a pipeline node, a straight pipe, a hollow copper pipe, a copper wire armor, a fin group and a water outlet pipe, wherein the straight pipe is arranged below the pipeline node, the hollow copper pipe is arranged on the inner side of the pipeline node, the copper wire armor is arranged on the outer side of the hollow copper pipe, the fin group is arranged on the outer side of the copper wire armor, the water outlet pipe is arranged at the end part of the hollow copper pipe, and a wind ring component assembled by bolts is arranged on the top side of the supporting component.

The improved structure is characterized in that the supporting component comprises a spring group, an upper rod, a side rod group and a pipeline frame, the elastic coefficient of the spring group is larger than the pressure of the upper rod, the side rod group is arranged on the inner side of the upper rod, and the pipeline frame is arranged outside the upper rod.

The shell assembly comprises a bolt side plate, a grid baffle and a bolt beam, wherein the bolt beam assembled by bolts is arranged on the inner side of the bolt side plate, and the grid baffle is connected to the outer side of the bolt beam in a clamping mode.

The improved structure is characterized in that the pipeline nodes are perpendicular to the straight pipes, the hollow copper pipes are vertically distributed on the inner sides of the pipeline nodes, and the hollow copper pipes are distributed in a transverse three-longitudinal five-array mode.

The hollow copper pipe is coated and attached with the copper wire armor, and the fin groups are vertically distributed on multiple groups outside the hollow copper pipe.

The improved structure is characterized in that the wind ring component comprises a culvert pipe, a support, a motor, fan blades and a grid cover, three groups of culvert pipes distributed in parallel are distributed above the wind ring component, the support is arranged on the inner side of the culvert pipe, the motor is arranged above the support to drive the fan blades to rotate, and the grid cover is arranged on the top side of the culvert pipe.

The utility model has the beneficial effects that:

the utility model mainly utilizes a plurality of groups of condenser pipes distributed in an array to match with nodes at two ends to uniformly convey water, so that the temperature difference of a radiating pipeline is reduced, and because a plurality of copper wire assemblies are wound and coated on the outer side of the pipeline, the radiating efficiency is improved, the strength and toughness of the assemblies are increased, the equipment cannot be burst and other accidents in long-time use.

Drawings

FIG. 1 is a schematic perspective view of the present invention;

FIG. 2 is a schematic bottom perspective view of the present invention;

FIG. 3 is a schematic perspective view of a bolt side plate and a grid baffle of the present invention;

FIG. 4 is a schematic view of a three-dimensional structure of a hollow copper tube and a copper wire armor according to the present invention;

figure 5 is a schematic perspective view of the culvert pipe and the bracket of the present invention.

Wherein: 1. a support pad; 2. a support assembly; 201. a spring set; 202. a rod is arranged; 203. a side bar group; 204. a pipe rack; 3. a housing assembly; 301. a bolt side plate; 302. a grid baffle; 303. a latch beam; 4. a condensing mechanism; 401. a pipe node; 402. a straight pipe; 403. a hollow copper tube; 404. copper wire armor; 405. a fin set; 406. a water outlet pipe; 5. a windband assembly; 501. a culvert pipe; 502. a support; 503. an electric motor; 504. a fan blade; 505. and (4) grid cover.

Detailed Description

In order to further understand the present invention, the following detailed description will be made with reference to the following examples, which are only used for explaining the present invention and are not to be construed as limiting the scope of the present invention.

As shown in fig. 1, 2, 3, 4, and 5, the present embodiment provides a finned condenser with a supporting structure, which includes a supporting pad 1 and a condensing mechanism 4, wherein a supporting assembly 2 is supported on a top side of the supporting pad 1, a shell assembly 3 is disposed on an inner side of the supporting assembly 2, and the condensing mechanism 4 is supported on an outer side of the supporting assembly 2;

condensation mechanism 4 includes pipeline node 401, straight tube 402, cavity copper pipe 403, copper wire armour 404, fin group 405 and outlet pipe 406, and the below of pipeline node 401 is provided with straight tube 402, and the interior limit side of pipeline node 401 is provided with cavity copper pipe 403, and the outside of cavity copper pipe 403 is provided with copper wire armour 404, and the outside of copper wire armour 404 is provided with fin group 405, and the tip of cavity copper pipe 403 is provided with outlet pipe 406, and the top side of supporting component 2 is provided with the wind circle subassembly 5 of bolt assembly.

The support assembly 2 comprises a spring group 201, an upper rod 202, a side rod group 203 and a pipeline frame 204, the elastic coefficient of the spring group 201 is larger than the pressure of the upper rod 202, the side rod group 203 is arranged on the inner side of the upper rod 202, the pipeline frame 204 is arranged outside the upper rod 202, and the spring group 201 is large in elasticity, so that the effect of supporting the upper rod 202 to achieve shock absorption for equipment can be achieved.

The shell assembly 3 comprises a bolt side plate 301, a grid baffle plate 302 and a bolt beam 303, the bolt beam 303 assembled by bolts is arranged on the inner side of the bolt side plate 301, the grid baffle plate 302 is connected to the outer side of the bolt beam 303 in a clamping mode, the bolt beam 303 with two ends distributed in parallel is assembled by the bolt side plate 301 on the inner side of the shell assembly 3, the grid baffle plate 302 is connected to the outer side of the bolt beam 303 in a clamping mode, and therefore the effect that the enclosure achieves protection of equipment is achieved.

Pipeline node 401 and straight tube 402 mutually perpendicular, and cavity copper pipe 403 vertical distribution is in the inboard of pipeline node 401, and cavity copper pipe 403 presents horizontal three and indulges five array distributions, has set up pipeline frame 204 in the outside side of upper boom 202 and has supported condensing mechanism 4, makes then high temperature liquid flow into pipeline node 401 through condensing mechanism 4, utilizes the straight tube 402 water conservancy diversion of the avris of pipeline node 401 to during the cavity copper pipe 403, thereby makes equipment area of contact increase reach the effect that enlarges the radiating efficiency.

The hollow copper pipe 403 and the copper wire armor 404 are coated and attached, the fin groups 405 are vertically distributed on multiple groups of the outer portion of the hollow copper pipe 403, and the copper wire armor 404 arranged on the outer side of the hollow copper pipe 403 is wound and attached with multiple beams, so that the heat dissipation efficiency is improved, and the heat dissipation efficiency is expanded by the fin groups 405.

The wind-ring subassembly 5 includes duct pipe 501, support 502, motor 503, flabellum 504 and net cover 505, the top of wind-ring subassembly 5 distributes and has three groups of duct pipe 501 of parallel distribution, duct pipe 501's inboard is provided with support 502, and support 502's top is provided with motor 503 drive flabellum 504 and rotates, duct pipe 501's top side is provided with net cover 505, because wind-ring subassembly 5 includes three groups of parallel distribution's duct pipe 501, and duct pipe 501's top side is provided with net cover 505 protection, can set up support 502 in duct pipe 501's inside and rotate with supporting motor 503 drive flabellum 504, release the effect that equipment reaches the heat dissipation condensation with the air of high temperature.

The working principle of the finned condenser with the supporting structure is as follows: as shown in fig. 1-5, firstly, a user can use the supporting component 2 above the supporting pad 1, because the spring set 201 has a larger elasticity, the effect of supporting the upper rod 202 to absorb shock for the device can be achieved, a plurality of sets of side rod sets 203 distributed in parallel can be arranged on the inner side of the upper rod 202, the end of the side rod set 203 can be attached to the upper shell component 3, the bolt beams 303 distributed in parallel at two ends can be assembled on the inner side of the shell component 3 by using the bolt side plates 301, and the outer side of the bolt beams 303 is connected with the grid baffle 302 in a clamping manner to form an enclosure to achieve the effect of protecting the device, the pipeline frame 204 can be arranged on the outer side of the upper rod 202 to support the condensing mechanism 4, then high-temperature liquid flows into the pipeline node 401 through the condensing mechanism 4, the high-temperature liquid is guided into the hollow copper pipe 403 by using the straight pipe 402 on the side of the pipeline node 401, because the copper wire armor 404 arranged on the outer side of the hollow copper pipe 403 is wound with a plurality of bundles, thereby radiating efficiency has been increased, and utilize fin group 405 to enlarge radiating efficiency, can set up wind circle subassembly 5 in the top of last pole 202, because wind circle subassembly 5 includes three groups of parallel distribution's culvert pipe 501, and the top side of culvert pipe 501 is provided with the protection of net cover 505, can set up support 502 in the inside of culvert pipe 501 in order to support good motor 503 drive flabellum 504 and rotate, release the air of high temperature equipment and reach the effect of heat dissipation condensation, the liquid of high temperature passes through outlet pipe 406 discharge apparatus after the heat dissipation is accomplished, therefore, accomplish a series of works.

The foregoing illustrates and describes the principles, general features, and advantages of the present invention. It will be understood by those skilled in the art that the present invention is not limited to the embodiments described above, which are described in the specification and illustrated only to illustrate the principle of the present invention, but that various changes and modifications may be made therein without departing from the spirit and scope of the present invention, which fall within the scope of the utility model as claimed. The scope of the utility model is defined by the appended claims and equivalents thereof.

Claims

1. The utility model provides a finned condenser with bearing structure, includes supporting pad (1) and condensing equipment (4), its characterized in that: a supporting assembly (2) is supported on the top side of the supporting pad (1), a shell assembly (3) is arranged on the inner side of the supporting assembly (2), and a condensing mechanism (4) is supported on the outer side of the supporting assembly (2);

condensation mechanism (4) are including pipeline node (401), straight tube (402), cavity copper pipe (403), copper wire armour (404), fin group (405) and outlet pipe (406), the below of pipeline node (401) is provided with straight tube (402), the interior limit side of pipeline node (401) is provided with cavity copper pipe (403), just the outside of cavity copper pipe (403) is provided with copper wire armour (404), the outside of copper wire armour (404) is provided with fin group (405), the tip of cavity copper pipe (403) is provided with outlet pipe (406), the top side of supporting component (2) is provided with wind circle subassembly (5) of bolt assembly.

2. The finned condenser having a support structure of claim 1, wherein: the support assembly (2) comprises a spring set (201), an upper rod (202), a side rod set (203) and a pipeline frame (204), the elastic coefficient of the spring set (201) is larger than the pressure of the upper rod (202), the side rod set (203) is arranged on the inner side of the upper rod (202), and the pipeline frame (204) is arranged outside the upper rod (202).

3. The finned condenser having a support structure of claim 1, wherein: the shell assembly (3) comprises a bolt side plate (301), a grid baffle plate (302) and a bolt beam (303), the bolt beam (303) assembled by bolts is arranged on the inner side of the bolt side plate (301), and the grid baffle plate (302) is connected to the outer side of the bolt beam (303) in a clamping mode.

4. The finned condenser having a support structure of claim 1, wherein: the pipeline nodes (401) are perpendicular to the straight pipes (402), the hollow copper pipes (403) are vertically distributed on the inner sides of the pipeline nodes (401), and the hollow copper pipes (403) are distributed in a transverse three-longitudinal five-array mode.

5. The finned condenser having a support structure of claim 4 wherein: the hollow copper pipe (403) is coated and attached with the copper wire armor (404), and the fin groups (405) are vertically distributed on multiple groups outside the hollow copper pipe (403).

6. The finned condenser having a support structure of claim 5 wherein: the wind ring component (5) comprises a duct pipe (501), a support (502), an electric motor (503), fan blades (504) and a grid cover (505), three groups of duct pipes (501) distributed in parallel are distributed above the wind ring component (5), the support (502) is arranged on the inner side of the duct pipe (501), the electric motor (503) is arranged above the support (502) to drive the fan blades (504) to rotate, and the grid cover (505) is arranged on the top side of the duct pipe (501).