CN210861826U - Condenser flow path structure, condenser and air conditioner - Google Patents

Abstract

The utility model discloses a condenser flow path structure, a condenser and an air conditioner, wherein the condenser flow path structure comprises a main pipe, a shunt pipe, a first connecting pipe and a second connecting pipe, the main pipe is connected with one end of the shunt pipe, and the other end of the shunt pipe is respectively connected with a first inlet pipe of the first connecting pipe and a second inlet pipe of the second connecting pipe, so that fluid flows through the shunt pipe along the main pipe and then flows to the first inlet pipe and the second inlet pipe in a balanced manner; the first connecting pipe also comprises a first elbow connecting pipe and a first outlet pipe, so that the fluid flows to the first outlet pipe along the first elbow connecting pipe; the second connecting pipe also comprises a second elbow connecting pipe and a second outlet pipe, so that the fluid flows to the second outlet pipe along the second elbow connecting pipe. The number of the condenser flow paths is increased, the flow of each flow path is reduced, the flow resistance in the pipe is further reduced, the heat exchange and transfer effects between the inside and the outside of the pipe are improved, and the efficient and energy-saving effects of the condenser are achieved.

Description

Condenser flow path structure, condenser and air conditioner

Technical Field

The utility model relates to a technical field of air conditioner especially involves a condenser flow path structure and condenser, air conditioner.

Background

The condenser flow path structure is an energy-saving device for realizing heat transfer between two or more than two fluids with different temperatures, and is used for transferring heat from the fluid with higher temperature to the fluid with lower temperature so that the temperature of the fluid reaches the index specified by the flow to meet the requirements of process conditions, and is also one of main devices for improving the energy utilization rate.

Most of the low-power air conditioners of integral type compact structure, condenser flow path structure size restriction, heat transfer area increase difficulty, consequently need solve the problem that heat transfer efficiency is low from the flow path urgently to reach energy-efficient.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing a condenser flow path structure and condenser, air conditioner aims at solving the problem that condenser flow path structure heat transfer area is little, and heat exchange efficiency is low in the air conditioner.

The utility model provides a condenser flow path structure, which is applied to a condenser and comprises a main pipe, a shunt pipe, a first connecting pipe and a second connecting pipe, wherein the main pipe is connected with one end of the shunt pipe, and the other end of the shunt pipe is respectively connected with a first inlet pipe of the first connecting pipe and a second inlet pipe of the second connecting pipe, so that fluid flows through the shunt pipe along the main pipe and then flows to the first inlet pipe and the second inlet pipe in a balanced manner;

the first connecting pipe also comprises a first elbow connecting pipe and a first outlet pipe, one end of the first elbow connecting pipe is connected with the first inlet pipe, and the other end of the first elbow connecting pipe is connected with the first outlet pipe, so that the fluid flows to the first outlet pipe along the first elbow connecting pipe;

the second connecting pipe also comprises a second elbow connecting pipe and a second outflow pipe, one end of the second elbow connecting pipe is connected with the second inflow pipe, and the other end of the second elbow connecting pipe is connected with the second outflow pipe, so that the fluid flows along the second elbow connecting pipe to the second outflow pipe.

Furthermore, the first connecting pipe also comprises at least one first Y-shaped connecting pipe, the first elbow connecting pipe comprises two first sub-elbow connecting pipes and two second sub-elbow connecting pipes, and the first outflow pipe comprises two first sub-outflow pipes and two second sub-outflow pipes;

first inlet pipe passes through first Y type connecting pipe respectively with first sub-elbow connecting pipe second sub-elbow connecting pipe is connected, first sub-elbow connecting pipe is kept away from the one end of first Y type connecting pipe is connected first sub-outlet pipe is in order to form first class branch road, second sub-elbow connecting pipe is kept away from the one end of first Y type connecting pipe is connected the second sub-outlet pipe is in order to form second class branch road, makes fluid follows respectively first sub-outlet pipe with the flow of second sub-outlet pipe flows.

Furthermore, the first elbow connecting pipe comprises a first straight pipe, a second straight pipe and a first semicircular connecting pipe, and two ends of the first semicircular connecting pipe are respectively connected with the first straight pipe and the second straight pipe.

Furthermore, a first straight pipe of one first elbow connecting pipe is connected with a first straight pipe of the other first elbow connecting pipe, so that the two first elbow connecting pipes are connected to form an S shape.

Furthermore, the fluid-conveying device also comprises a three-way connecting pipe, wherein the first sub-outflow pipe and the second sub-outflow pipe are both connected with the three-way connecting pipe, so that the fluid flows out of the three-way connecting pipe.

Furthermore, one end of the flow dividing pipe is connected with the main pipe, and the other end of the flow dividing pipe is provided with a flaring section for connecting the first inflow pipe and the second inflow pipe, so that the fluid flows to the first inflow pipe and the second inflow pipe in a balanced manner.

Further, the outer diameter of the flaring section is smaller than the inner diameter of the first connecting pipe and the inner diameter of the second connecting pipe, so that the flaring section is inserted into the first connecting pipe to be tightly matched, or the flaring section is inserted into the second connecting pipe to be tightly matched.

Furthermore, the second connecting pipe also comprises at least one second Y-shaped connecting pipe, the second elbow connecting pipe comprises two connecting pipes which are respectively a third sub-elbow connecting pipe and a fourth sub-elbow connecting pipe, and the second outflow pipe comprises two connecting pipes which are respectively a third sub-outflow pipe and a fourth sub-outflow pipe;

the second inlet pipe passes through second Y type connecting pipe respectively with third sub-elbow connecting pipe fourth sub-elbow connecting pipe is connected, third sub-elbow connecting pipe is kept away from the one end of second Y type connecting pipe is connected third sub-outlet pipe is in order to form third stream branch road, fourth sub-elbow connecting pipe is kept away from the one end of second Y type connecting pipe is connected fourth sub-outlet pipe is in order to form fourth stream branch road, makes the fluid follow respectively third sub-outlet pipe with fourth sub-outlet pipe flow stream flows.

The utility model also provides a condenser, including the aforesaid condenser flow path structure.

The utility model also provides an air conditioner, including the aforesaid condenser.

The utility model discloses a condenser flow path structure and condenser, air conditioner, the beneficial effect who has do, through the quantity that increases the condenser flow path, reduces the flow of each flow path, and then reduces intraductal flow resistance, has improved the heat transfer transmission effect between the inside and outside pipe, has realized the energy-efficient effect of condenser.

Drawings

Fig. 1 is a schematic structural diagram of a flow path structure of a condenser according to an embodiment of the present invention;

fig. 2 is a partially enlarged view of a portion a in fig. 1.

The objects, features and advantages of the present invention will be further described with reference to the accompanying drawings.

Detailed Description

It should be understood that the specific embodiments described herein are merely illustrative of the invention and are not intended to limit the invention.

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 efforts belong to the protection scope of the present invention.

It should be noted that all the directional indicators (such as upper, lower, left, right, front and rear … …) in the embodiments of the present invention are only used to explain the relative position relationship between the components, the motion situation, etc. in a specific posture (as shown in the drawings), and if the specific posture is changed, the directional indicator is also changed accordingly, and the connection may be a direct connection or an indirect connection.

In addition, descriptions in the present application as to "first", "second", and the like are for descriptive purposes only and are not to be construed as indicating or implying relative importance or implicit to the number of technical features indicated. Thus, a feature defined as "first" or "second" may explicitly or implicitly include at least one such feature. In addition, the technical solutions in the embodiments may be combined with each other, but it must be based on the realization of those skilled in the art, and when the technical solutions are contradictory or cannot be realized, the combination of the technical solutions should not be considered to exist, and is not within the protection scope of the present invention.

Referring to fig. 1-2, a flow path structure of a condenser, applied to a condenser, includes a main pipe 2, a shunt pipe 3, a first connection pipe 4 and a second connection pipe 5, wherein the main pipe 2 is connected to one end of the shunt pipe 3, and the other end of the shunt pipe 3 is connected to a first inlet pipe of the first connection pipe 4 and a second inlet pipe of the second connection pipe 5 respectively, so that fluid flows through the shunt pipe 3 along the main pipe 2 and then flows to the first inlet pipe of the first connection pipe 4 and the second inlet pipe of the second connection pipe 5 in a balanced manner; the first connecting pipe 4 further comprises a first elbow connecting pipe 41 and a first outlet pipe, one end of the first elbow connecting pipe 41 is connected with the first inlet pipe, and the other end of the first elbow connecting pipe 41 is connected with the first outlet pipe, so that the fluid flows to the first outlet pipe along the first elbow connecting pipe 41; the second connection pipe 5 further includes a second elbow connection pipe 51 and a second outlet pipe, one end of the second elbow connection pipe 51 is connected to the second inlet pipe, and the other end is connected to the second outlet pipe, so that the fluid flows to the second outlet pipe along the second elbow connection pipe 51.

The Condenser (Condenser), a component of refrigeration system, belongs to one kind of heat exchanger, can change gas or vapour into liquid, transfer the heat in the tube to the air near the tube periphery in a faster way, let the heat lose to the air all around, the Condenser working process is a heat release process.

The utility model discloses in, the fluid is gaseous or liquid or gas-liquid mixture's medium for the heat dissipation. The condenser with the condenser flow path structure is mainly used for an integrated low-power air conditioner, the design of the condenser flow path structure is more compact due to the small size of the air conditioner, the number of flow paths is increased in the condenser flow path structure to reduce the flow of the flow paths and further reduce the flow resistance in the pipes, the condenser flow path structure is installed and fixed on one side face of a fixing frame 1 of the air conditioner, the condenser of the air conditioner can be effectively cooled, the heat exchange efficiency is improved, and the efficient and energy-saving effects are achieved.

In this embodiment, the condenser flow path structure includes a main pipe 2, a shunt pipe 3, a first connection pipe 4 and a second connection pipe 5, the main pipe 2 is connected to the first connection pipe 4 and the second connection pipe 5 through the shunt pipe 3, the first connection pipe 4 includes a first inlet pipe, a first elbow connection pipe 41 and a first outlet pipe, wherein the shunt pipe 3, the first inlet pipe, the first elbow connection pipe 41 and the first outlet pipe are connected in sequence, a fluid flows from the main pipe 2 to the first inlet pipe through the shunt pipe 3, then flows through the first elbow connection pipe 41 and the first outlet pipe in sequence, flows out from the first outlet pipe, and heat transfer is performed through air at the outer peripheries of all the pipes, so as to achieve a heat dissipation effect; second connecting pipe 5 includes the second and advances the flow tube, second elbow connecting pipe and second play flow tube, wherein, shunt tubes 3, the second advances the flow tube, second elbow connecting pipe, the second play flow tube connects gradually, the fluid advances and flows to the second from being responsible for 2 through shunt tubes 3, loop through second elbow connecting pipe and second play flow tube again, flow out from the second play flow tube, the in-process that the fluid flows carries out the heat transfer with the air of the outside periphery of pipeline, realize the radiating effect. Further improve heat transfer effect through the reposition of redundant personnel structure that sets up two runners, wherein, the one end of shunt tubes 3 is connected and is responsible for 2, first connecting pipe 4 and second connecting pipe 5 are connected to the other end, fluid flows to shunt tubes 3 through being responsible for 2, but the first inlet pipe of the first connecting pipe 4 of balanced flow direction and the second inlet pipe of second connecting pipe 5 behind the fluid outflow shunt tubes 3, refrigerant maldistribution has not only been overcome, the heat exchange efficiency of full play condenser, improve the heat transfer volume of condenser, and reduce the flow of runner through the reposition of redundant personnel, reduce the resistance of intraductal flow, realize the high-efficient energy-conservation of condenser.

In this embodiment, the first connecting pipe 4 further includes at least one first Y-shaped connecting pipe, the first elbow connecting pipe 41 includes two first sub-elbow connecting pipes and two second sub-elbow connecting pipes, and the first outflow pipes include two first sub-outflow pipes and two second sub-outflow pipes; the first inlet pipe is connected with the first sub-elbow connecting pipe and the second sub-elbow connecting pipe through the first Y-shaped connecting pipe respectively, one end, far away from the first Y-shaped connecting pipe, of the first sub-elbow connecting pipe is connected with the first sub-outlet pipe to form a first outlet branch, one end, far away from the first Y-shaped connecting pipe, of the second sub-elbow connecting pipe is connected with the second sub-outlet pipe to form a second outlet branch, and therefore fluid flows out of the first sub-outlet pipe and the second sub-outlet pipe respectively.

In this embodiment, the first Y-shaped connecting pipe is used to connect one end of the first inflow pipe and the first sub-elbow connecting pipe, and the second sub-elbow connecting pipe, and then the first sub-elbow connecting pipe is connected to the first sub-outflow pipe to form the first flow branch, and the second sub-elbow connecting pipe is connected to the second sub-outflow pipe to form the second flow branch, so that the fluid can flow out from the first flow branch or the second flow branch, and by increasing the number of the flow paths in the first connecting pipe 4, the flow path of the first connecting pipe 4 is reduced, and further the flow resistance in the first connecting pipe 4 is reduced, thereby improving the heat exchange effect of the air outside the flow path and the pipeline, and improving the heat exchange.

In this embodiment, the first elbow connecting pipe 41 includes a first straight pipe 412, a second straight pipe 413 and a first semicircular connecting pipe 411, and two ends of the first semicircular connecting pipe 411 are respectively connected with the first straight pipe 412 and the second straight pipe 413. The first elbow connecting pipe 41 is a U-shaped pipe formed by connecting two ends of a first semicircular connecting pipe 411 to a first straight pipe 412 and a second straight pipe 413, and a plurality of first elbow connecting pipes 41 for connection are provided in the first connecting pipe 4 as needed, so that the plurality of first elbow connecting pipes 41 are connected to form a plurality of S-shapes, thereby extending the flow path of fluid in the pipes as long as possible, transferring heat with air outside the pipes, and improving the heat exchange efficiency of the condenser. In a specific embodiment, the first elbow connecting pipe 41 can be a hose, and can be adjusted to a required elbow connecting pipe as required, so that the installation is convenient.

In this embodiment, the first straight pipe 412 of one first elbow connecting pipe 41 is connected with the first straight pipe 412 of another first elbow connecting pipe 41, so that the two first elbow connecting pipes 41 are connected in an S shape. The second straight pipe 413 of the other first elbow connecting pipe 41 is connected with the first straight pipe 412 of the other first elbow connecting pipe 41, so that the plurality of first elbow connecting pipes 41 are connected to form a pipeline for fluid to flow, and the plurality of S-shaped connecting pipes are arranged, so that the flow path of fluid in the pipe can be prolonged as much as possible, heat is transferred with air outside the pipe, and the heat exchange efficiency of the condenser is improved.

In this embodiment, the fluid-cooled generator further includes a three-way connection pipe, and the first sub-outflow pipe and the second sub-outflow pipe are both connected to the three-way connection pipe, so that the fluid flows out from the three-way connection pipe.

In this embodiment, one end of the shunt tube 3 is connected to the main tube 2, and the other end is provided with an opening expanding section for connecting the first inlet tube and the second inlet tube, so that the fluid flows to the first inlet tube and the second inlet tube in a balanced manner.

In the present embodiment, the outer diameter of the flared section is smaller than the inner diameter of the first connection pipe 4 and the inner diameter of the second connection pipe 5, so that the flared section is inserted into the first connection pipe 4 to be closely fitted, or the flared section is inserted into the second connection pipe 5 to be closely fitted.

In this embodiment, shunt tubes 3's one end and being responsible for 2 and being connected, the other end is provided with the flaring section, this flaring section is used for linking to each other with first connecting pipe 4 or second connecting pipe 5, wherein, the external diameter at flaring section department slightly is less than the internal diameter of first connecting pipe 4 or the internal diameter of second connecting pipe 5, be used for guaranteeing that the shunt tubes inserts the first inlet tube of first connecting pipe 4, and when inserting the second inlet tube of second connecting pipe 5, both can closely cooperate, realize fluidic effective transmission.

In this embodiment, the second connecting pipe 5 further includes at least one second Y-shaped connecting pipe, the second elbow connecting pipe includes two second elbow connecting pipes, which are respectively a third sub-elbow connecting pipe and a fourth sub-elbow connecting pipe, and the second outflow pipe includes two second outflow pipes, which are respectively a third sub-outflow pipe and a fourth sub-outflow pipe; the second inflow pipe is respectively connected with a third sub-elbow connecting pipe and a fourth sub-elbow connecting pipe through a second Y-shaped connecting pipe, one end, far away from the second Y-shaped connecting pipe, of the third sub-elbow connecting pipe is connected with a third sub-outflow pipe to form a third outflow branch, one end, far away from the second Y-shaped connecting pipe, of the fourth sub-elbow connecting pipe is connected with a fourth sub-outflow pipe to form a fourth outflow branch, and fluid flows out of the third sub-outflow pipe and the fourth sub-outflow pipe respectively.

In this embodiment, the second Y-shaped connection pipe is used to connect one end of the second inlet pipe, the third sub-elbow connection pipe, and the fourth sub-elbow connection pipe, and then the third sub-elbow connection pipe is connected to the third sub-outlet pipe to form a third flow branch, and the fourth sub-elbow connection pipe is connected to the fourth sub-outlet pipe to form a fourth flow branch, so that the fluid can flow out from the third flow branch or the fourth flow branch, and by increasing the number of flow paths in the second connection pipe 5, the flow path of the second connection pipe 5 is reduced, thereby reducing the flow resistance in the second connection pipe 5, improving the heat exchange effect between the flow path and the air outside the pipe, and improving the heat exchange efficiency of the condenser.

The utility model discloses in, the mode and the structure that first connecting pipe 4 is connected can be adopted in the setting of second connecting pipe 5 and the flow direction of runner, adopt the same structure, the time of processing can be saved.

The utility model also provides a condenser, including above-mentioned condenser flow path structure.

The utility model discloses in, the condenser has adopted foretell condenser flow path structure to realize the heat transfer process of condenser.

The utility model also provides an air conditioner, including the condenser flow path structure of above-mentioned condenser and adoption.

The utility model discloses in, the air conditioner adopts the condenser of the above-mentioned condenser flow path structure of application, the heat transfer process of realization air conditioner that can be better to realize giving out heat of air conditioner.

The utility model discloses a condenser flow path structure and condenser, air conditioner through the quantity that increases the condenser flow path, reduces the flow of each flow path, and then reduces intraductal flow resistance, has improved the heat transfer transmission effect between the inside and outside pipe, has realized the energy-efficient effect of condenser.

The above only is the preferred embodiment of the present invention, not limiting the scope of the present invention, all the equivalent structures or equivalent flow changes made by the contents of the specification and the drawings, or directly or indirectly applied to other related technical fields, are included in the same way in the protection scope of the present invention.

Claims (10)

1. A condenser flow path structure is applied to a condenser and is characterized by comprising a main pipe, a flow dividing pipe, a first connecting pipe and a second connecting pipe, wherein the main pipe is connected with one end of the flow dividing pipe, and the other end of the flow dividing pipe is respectively connected with a first flow inlet pipe of the first connecting pipe and a second flow inlet pipe of the second connecting pipe, so that fluid flows through the flow dividing pipe along the main pipe and then flows to the first flow inlet pipe and the second flow inlet pipe in a balanced manner;

the first connecting pipe also comprises a first elbow connecting pipe and a first outlet pipe, one end of the first elbow connecting pipe is connected with the first inlet pipe, and the other end of the first elbow connecting pipe is connected with the first outlet pipe, so that the fluid flows to the first outlet pipe along the first elbow connecting pipe;

the second connecting pipe also comprises a second elbow connecting pipe and a second outflow pipe, one end of the second elbow connecting pipe is connected with the second inflow pipe, and the other end of the second elbow connecting pipe is connected with the second outflow pipe, so that the fluid flows along the second elbow connecting pipe to the second outflow pipe.

2. The condenser flow path structure according to claim 1, wherein the first connection pipe further comprises at least one first Y-shaped connection pipe, the first elbow connection pipe comprises two, respectively, first sub-elbow connection pipes and second sub-elbow connection pipes, and the first outflow pipe comprises two, respectively, first sub-outflow pipes and second sub-outflow pipes;

first inlet pipe passes through first Y type connecting pipe respectively with first sub-elbow connecting pipe second sub-elbow connecting pipe is connected, first sub-elbow connecting pipe is kept away from the one end of first Y type connecting pipe is connected first sub-outlet pipe is in order to form first class branch road, second sub-elbow connecting pipe is kept away from the one end of first Y type connecting pipe is connected the second sub-outlet pipe is in order to form second class branch road, makes fluid follows respectively first sub-outlet pipe with the flow of second sub-outlet pipe flows.

3. The condenser flow path structure according to claim 1 or 2, wherein the first elbow connection pipe includes a first straight pipe, a second straight pipe, and a first semicircular connection pipe, both ends of which are connected to the first straight pipe and the second straight pipe, respectively.

4. The condenser flow path structure according to claim 3, wherein a first straight pipe of one of the first elbow connection pipes is connected to a first straight pipe of the other first elbow connection pipe so that the two first elbow connection pipes are connected in an S-shape.

5. The condenser flow path structure according to claim 2, further comprising a three-way connection pipe, and the first sub-outflow pipe and the second sub-outflow pipe are each connected to the three-way connection pipe so that the fluid flows out of the three-way connection pipe.

6. The condenser flow path structure according to claim 1, wherein the flow dividing pipe has one end connected to the main pipe and the other end provided with a flared section for connecting the first and second flow inlet pipes so that the fluid flows toward the first and second flow inlet pipes in a balanced manner.

7. The condenser flow path structure according to claim 6, wherein an outer diameter of the flared section is smaller than an inner diameter of the first connecting pipe and an inner diameter of the second connecting pipe, so that the flared section is inserted into the first connecting pipe to be tightly fitted, or the flared section is inserted into the second connecting pipe to be tightly fitted.

8. The condenser flow path structure according to claim 1, wherein the second connection pipe further comprises at least one second Y-shaped connection pipe, the second elbow connection pipe comprises two, respectively, a third sub-elbow connection pipe and a fourth sub-elbow connection pipe, and the second outflow pipe comprises two, respectively, a third sub-outflow pipe and a fourth sub-outflow pipe;

the second inlet pipe passes through second Y type connecting pipe respectively with third sub-elbow connecting pipe fourth sub-elbow connecting pipe is connected, third sub-elbow connecting pipe is kept away from the one end of second Y type connecting pipe is connected third sub-outlet pipe is in order to form third stream branch road, fourth sub-elbow connecting pipe is kept away from the one end of second Y type connecting pipe is connected fourth sub-outlet pipe is in order to form fourth stream branch road, makes the fluid follow respectively third sub-outlet pipe with fourth sub-outlet pipe flow stream flows.

9. A condenser comprising the condenser flow path structure of any one of claims 1 to 8.

10. An air conditioner characterized by comprising the condenser of claim 9.

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