CN210165579U - Air pipe connector structure - Google Patents

Abstract

The utility model discloses an air pipe interface structure, through setting up the interface external member and the external member that generates heat. The heating external member is arranged in the interface external member, so that the equipment does not need to be additionally provided with a heating device for heating to generate warm air, the whole volume of the equipment is reduced to a certain extent, and meanwhile, the manufacturing cost of the equipment is reduced; in addition, the equipment is no longer used as a generating source of the warm air, so that the transmission distance of the warm air can be reduced to a certain extent, the heat exchange between the warm air and the outside air in the transmission process is prevented, and the heating efficiency is reduced; in addition, the arrangement of the plurality of radiating fin top sheets and the plurality of radiating fin bottom sheets can greatly increase the heat exchange efficiency between the semiconductor heating element and the air, quickly dissipate heat into the air and improve the heating efficiency; moreover, all be provided with the interval between two adjacent heat dissipation wing top sheets and all be provided with the interval between two adjacent heat dissipation wing film, play the effect of rectification to the warm braw, regular warm braw wind direction improves the external member that generates heat and to the heating efficiency in appointed region.

Description

Air pipe connector structure

Technical Field

The utility model relates to an tuber pipe technical field especially relates to an tuber pipe interface structure.

Background

Currently, ductwork is a duct system for air delivery and distribution. There are two kinds of composite air pipe and inorganic air pipe. The composite air duct is represented by an air duct. They can be classified according to their sectional shapes and materials. The stainless steel air duct is manufactured by coating sealant at seams such as seaming seam, rivet seam, flange flanging four corners, etc. Before the sealant is coated, dust and oil stains on the surface are removed. According to the cross section shape, the air pipe can be divided into a circular air pipe, a rectangular air pipe, an oblate air pipe and the like, wherein the circular air pipe has the smallest resistance but the largest height and size, and is complex to manufacture. So the application is mainly based on a rectangular air pipe. The air pipe can be divided into a metal air pipe, a composite air pipe and a polymer air pipe according to the material. When the air pipe conveys the air quantity, the operation of conveying the air quantity must be carried out through the air pipe connector communicating equipment.

In the existing household life, especially in cold winter, more and more devices generate warm air, such as air conditioners, and then the devices are connected into an air pipe through an air pipe connector to convey the warm air to each position in a room to finish the heating work of the devices. Firstly, in order to generate warm air, a heating device must be additionally arranged in the equipment, but the additional arrangement of the heating device can increase the overall volume of the equipment and also can increase the cost of the equipment; secondly, because the equipment is a generating source of the warm air, if the warm air is required to be provided for a large-area, the equipment must be operated with larger operation power, otherwise, the warm air generated by the equipment passes through the air pipe connector and a plurality of air pipes, and is inevitably subjected to heat exchange with air on the way, namely, the temperature of the warm air is reduced to a certain extent, so that the heating work cannot be completed for the designated area; third, blow off the back from the tuber pipe when the warm braw, the wind direction of warm braw is comparatively mixed and disorderly, and equipment is taken as warm braw and takes place the source but can't play the effect of rectification to blowing off the warm braw, and the direction that the unable regular warm braw of equipment blew off promptly leads to the efficiency of heating to lower by a wide margin.

SUMMERY OF THE UTILITY MODEL

The utility model aims at overcoming the weak point among the prior art, providing one kind can not increase the whole volume of equipment, and the manufacturing cost is lower, can not lead to heating efficiency to reduce because of long distance transmission warm braw, the efficient tuber pipe interface structure who reaches possess the rectification function of heating.

The purpose of the utility model is realized through the following technical scheme:

an air duct interface structure comprising:

the connector comprises a connector body and a protective shell, wherein one end of the connector body is communicated with an external air pipe, the other end of the connector body is communicated with the protective shell, and a plurality of avoiding holes are formed in the side wall of the protective shell; and

the heating external member comprises an annular shell and a plurality of heaters, the heaters are sequentially stacked in the annular shell, in one heater, the heater comprises a semiconductor heating element, a positive conductive terminal, a negative conductive terminal, a plurality of radiating fin top sheets and a plurality of radiating fin bottom sheets, the semiconductor heating element is arranged in the annular shell, each heat dissipation fin top sheet is arranged on one side surface of the semiconductor heating element, and a space is arranged between every two adjacent heat dissipation fin top sheets, each heat dissipation fin bottom sheet is arranged on one side surface of the semiconductor heating element far away from each heat dissipation fin top sheet, and a space is arranged between every two adjacent heat dissipation fin bottom sheets, the positive conductive terminal is connected with the heat dissipation fin top sheet positioned at the starting end, and the negative conductive terminal is connected with the heat dissipation fin bottom sheet positioned at the starting end.

In one embodiment, the interface kit further includes a plurality of reinforcing ribs, each of the reinforcing ribs is connected to the interface tube body and the protective shell, and each of the reinforcing ribs is used for supporting the side wall of the annular shell when the annular shell is embedded in the protective shell.

In one embodiment, the interface kit comprises 12-18 reinforcing ribs.

In one embodiment, the interface kit further includes a fastening member, the fastening member is disposed on an outer wall of the protective housing, the fastening member is provided with a fastening portion, and the fastening member is used for fastening the annular housing when the annular housing is embedded in the protective housing.

In one embodiment, the protection shell is provided with a locking hole, the air duct interface structure further comprises a locking external member, the locking external member comprises a pressing holding member and a locking member, the pressing holding member is provided with a through hole, the locking member is used for the clamping part to clamp the annular shell, the locking member penetrates through the through hole, the end part of the locking member is screwed in the locking hole, and then the pressing holding member presses and holds the protection shell.

In one embodiment, the air duct interface structure further includes a plurality of anti-touch plates, each anti-touch plate is disposed in the interface tube body, and two adjacent anti-touch plates are spaced from each other.

In one embodiment, each of the anti-touch plates is located adjacent to an end of the interface tube.

In one embodiment, the interface tube and the protective housing are of one-piece construction.

In one embodiment, the conductive terminal and the negative conductive terminal are both provided with flow guide holes.

In one embodiment, the flow guide holes are round holes.

The utility model discloses compare in prior art's advantage and beneficial effect as follows:

the utility model discloses an air pipe interface structure, through setting up the interface external member and the external member that generates heat. In the practical application process, the heating external member is arranged in the interface external member, so that the equipment does not need to be additionally provided with a heating device for heating to generate warm air, the whole volume of the equipment is reduced to a certain extent, and meanwhile, the manufacturing cost of the equipment is reduced; in addition, the equipment is no longer used as a generating source of the warm air, so that the transmission distance of the warm air can be reduced to a certain extent, and the temperature of the warm air is prevented from being reduced due to heat exchange between the warm air and the outside air in the transmission process, and the heating efficiency is further reduced; in addition, the arrangement of the plurality of radiating fin top sheets and the plurality of radiating fin bottom sheets can greatly increase the heat exchange efficiency between the semiconductor heating element and the air, quickly dissipate the heat generated by the semiconductor heating element into the air and improve the heating efficiency; moreover, all be provided with the interval between two adjacent heat dissipation wing top sheets and all be provided with the interval between two adjacent heat dissipation wing film, can play the effect of rectification to the warm braw, regular warm braw's wind direction improves the external member that generates heat and to the heating efficiency in appointed region.

Drawings

In order to more clearly illustrate the technical solutions of the embodiments of the present invention, the drawings that are required to be used in the embodiments will be briefly described below, it should be understood that the following drawings only illustrate some embodiments of the present invention, and therefore should not be considered as limiting the scope, and for those skilled in the art, other related drawings can be obtained according to the drawings without inventive efforts.

Fig. 1 is a schematic structural view of an air duct joint structure according to an embodiment of the present invention;

fig. 2 is a schematic structural view of an air duct joint structure at another viewing angle according to an embodiment of the present invention;

fig. 3 is an exploded schematic view of an air duct joint structure according to an embodiment of the present invention.

Detailed Description

In order to facilitate understanding of the present invention, the present invention will be described more fully hereinafter with reference to the accompanying drawings. The preferred embodiments of the present invention are shown in the drawings. The invention may, however, be embodied in many different forms and should not be construed as limited to the embodiments set forth herein. Rather, these embodiments are provided so that this disclosure will be thorough and complete.

It will be understood that when an element is referred to as being "secured to" another element, it can be directly on the other element or intervening elements may also be present. When an element is referred to as being "connected" to another element, it can be directly connected to the other element or intervening elements may also be present. The terms "vertical," "horizontal," "left," "right," and the like as used herein are for illustrative purposes only and do not represent the only embodiments.

Unless defined otherwise, all technical and scientific terms used herein have the same meaning as commonly understood by one of ordinary skill in the art to which this invention belongs. The terminology used herein in the description of the invention is for the purpose of describing particular embodiments only and is not intended to be limiting of the invention. As used herein, the term "and/or" includes any and all combinations of one or more of the associated listed items.

Referring to fig. 1, an air duct joint structure 10 includes a joint member 100 and a heat generating member 200.

Thus, it should be noted that the interface kit 100 plays a role of transmitting warm air and installing the heating kit 200; the heating kit 200 is used for generating heat, and when the device generates air volume, the air volume flowing through the heating kit 200 is heat-exchanged with the heat, and is converted into warm air to blow off to the interface kit 100.

Referring to fig. 3, the interface kit 100 includes an interface tube 110 and a protective casing 120, one end of the interface tube 110 is communicated with an external air duct, the other end of the interface tube 110 is communicated with the protective casing 120, and a plurality of clearance holes 121 are formed on a side wall of the protective casing 120.

Therefore, it should be noted that the interface tube body 110 is used for connecting an external air duct and transmitting warm air to the external air duct; the protective housing 120 plays a role in installation and protection, and prevents the heat generating kit 200 from being damaged due to physical contact with an external object.

Referring to fig. 3 again, the heating assembly 200 includes an annular housing 210 and a plurality of heaters 220, each heater 220 is sequentially stacked in the annular housing 210, in a heater 220, the heater 220 includes a semiconductor heating element 221, a positive conductive terminal 222, a negative conductive terminal 223, a plurality of heat dissipation fin top sheets 224 and a plurality of heat dissipation fin bottom sheets 225, the semiconductor heating element 221 is disposed in the annular housing 210, each heat dissipation fin top sheet 224 is disposed on one side of the semiconductor heating element 221, and a space is arranged between two adjacent radiating fin top sheets 224, each radiating fin bottom sheet 225 is arranged on one side surface of the semiconductor heating element 221 far away from each radiating fin top sheet 224, and a space is arranged between every two adjacent heat dissipation fin bottom sheets 225, the positive conductive terminal 222 is connected with the heat dissipation fin top sheet 224 positioned at the starting end, and the negative conductive terminal 223 is connected with the heat dissipation fin bottom sheet 225 positioned at the starting end.

Therefore, it should be noted that, because the heating kit 200 is installed in the interface kit 100, the device does not need to be additionally provided with a heating device to generate heat to generate warm air, so that the overall size of the device is reduced to a certain extent, and meanwhile, the manufacturing cost of the device is reduced; in addition, the equipment is no longer used as a generating source of the warm air, so that the transmission distance of the warm air can be reduced to a certain extent, and the temperature of the warm air is prevented from being reduced due to heat exchange between the warm air and the outside air in the transmission process, and the heating efficiency is further reduced; in addition, the arrangement of the plurality of radiating fin top sheets 224 and the plurality of radiating fin bottom sheets 225 can greatly increase the heat exchange efficiency between the semiconductor heating element 221 and the air, quickly dissipate the heat generated by the semiconductor heating element 221 to the air, and improve the heating efficiency; moreover, all be provided with the interval between two adjacent heat dissipation wing top sheets 224 and all be provided with the interval between two adjacent heat dissipation wing bottom sheets 225, can play the effect of rectification to the warm braw, regular warm braw wind direction improves the external member 200 that generates heat and to the heating efficiency in appointed region.

It should be noted that when the heater 220 is activated, the voltage flows to the heat dissipation fin top plate 224 located at the starting end through the positive conductive terminal 222, the voltage flows to the semiconductor heating element 221, the semiconductor heating element 221 receives the voltage to operate and generate heat, the heat is dissipated to the air through the heat dissipation fin top plate 224 and the heat dissipation fin bottom plate 225, and performs rapid heat exchange with the air, and when the air generated by the device flows through the heat dissipation fin top plate 224 and the heat dissipation fin bottom plate 225, the absorbed heat is converted into warm air.

It should be noted that the heat dissipating fin top plate 224 at the starting end and the heat dissipating fin bottom plate 225 at the starting end are self-defined starting ends when the user installs the heat dissipating fin top plate, that is, the positive conductive terminal 222 is connected to the first heat dissipating fin top plate 224 defined by the user, the negative conductive terminal 223 is connected to the first heat dissipating fin bottom plate 225 defined by the user, and the voltage passes through the heat dissipating fin top plate 224 at the starting end and finally flows out from the negative conductive terminal 223.

Referring to fig. 3 again, when the annular housing 210 is embedded in the protective housing 110, the positive conductive terminal 222 and the negative conductive terminal 223 correspondingly fall into the avoiding hole 121.

Therefore, it should be noted that the avoidance hole 121 is formed to make the overall structure of the air duct joint structure 10 more compact, and reduce the overall volume of the air duct joint structure 10.

Further, referring to fig. 3 again, in an embodiment, the interface kit 100 further includes a plurality of reinforcing ribs 130, each reinforcing rib 130 is connected to the interface tube 110 and the protective shell 120, and when each reinforcing rib 130 is used for the annular shell 210 to be embedded in the protective shell 120, each reinforcing rib 130 supports against a sidewall of the annular shell 210.

As described above, the provision of the plurality of ribs 130 can improve the overall mechanical strength of the interface package 100 and prolong the service life of the interface package 100. Specifically, the interface kit includes 12 to 18 reinforcing ribs 130. In this manner, the number of the ribs 130 to be provided can be set flexibly in accordance with actual conditions.

Further, referring to fig. 3 again, in an embodiment, the interface kit 100 further includes a locking member 140, the locking member 140 is disposed on an outer wall of the protective housing 120, the locking member 140 is disposed with a locking portion, and the locking member 140 is used for locking the annular housing 210 when the annular housing 210 is embedded in the protective housing 120.

Therefore, it should be noted that the fastener 140 is used for limiting and fixing the annular housing 210, and when the annular housing 210 is embedded in the protective housing 120, the annular housing 210 is prevented from falling off from the protective housing 120.

Further, referring to fig. 3 again, in an embodiment, the protection housing 120 is provided with a locking hole 122, the air duct interface structure 10 further includes a locking kit, the locking kit includes a pressing member and a locking member, the pressing member is provided with a through hole, when the locking member is used for the fastening portion to clamp the annular housing 210, the locking member penetrates through the through hole, so that the end portion of the locking member is screwed into the locking hole, and the pressing member presses the protection housing 120.

So, it should be noted that, the setting of seting up and locking external member of locking hole 122, when annular casing 210 was put to the buckle portion card, the user was through wearing to establish the through-hole with the retaining member, made the tip spiro union of retaining member in the locking hole, and then held protective housing 120 in order to make the pressure to hold the piece pressure, adopted bolt locking's mode to accomplish the spacing fixed to protective housing 120 promptly, when further preventing that annular casing 210 from embedding protective housing 120 in, annular casing 210 drops from protective housing 120.

Further, referring to fig. 2, in an embodiment, the air duct interface structure 10 further includes a plurality of anti-touch plates 300, each anti-touch plate 300 is disposed in the interface duct body 110, and two adjacent anti-touch plates 300 are spaced apart from each other.

In this way, it should be noted that the touch panels 300 can prevent a human hand from directly contacting the heating kit 200 when the human hand is inserted into the interface tube 110, which may result in an electric shock accident. Specifically, each of the anti-touch plates 300 is located adjacent to one end of the interface tube 110.

Further, in one embodiment, the interface tube 110 and the protective housing 120 are an integrally formed structure.

In this way, it should be noted that the interface tube 110 and the protective housing 120 are designed as an integrally formed structure, so that the overall mechanical strength of the interface kit 100 can be improved, and the service life of the interface kit 100 can be prolonged.

Further, in one embodiment, the conductive terminal 222 and the negative conductive terminal 223 are both provided with a flow guiding hole.

Thus, it should be noted that the flow guide hole plays a role of connecting the electric wire. Specifically, the flow guide holes are round holes.

The utility model discloses an air pipe interface structure, through setting up the interface external member and the external member that generates heat. In the practical application process, the heating external member is arranged in the interface external member, so that the equipment does not need to be additionally provided with a heating device for heating to generate warm air, the whole volume of the equipment is reduced to a certain extent, and meanwhile, the manufacturing cost of the equipment is reduced; in addition, the equipment is no longer used as a generating source of the warm air, so that the transmission distance of the warm air can be reduced to a certain extent, and the temperature of the warm air is prevented from being reduced due to heat exchange between the warm air and the outside air in the transmission process, and the heating efficiency is further reduced; in addition, the arrangement of the plurality of radiating fin top sheets and the plurality of radiating fin bottom sheets can greatly increase the heat exchange efficiency between the semiconductor heating element and the air, quickly dissipate the heat generated by the semiconductor heating element into the air and improve the heating efficiency; moreover, all be provided with the interval between two adjacent heat dissipation wing top sheets and all be provided with the interval between two adjacent heat dissipation wing film, can play the effect of rectification to the warm braw, regular warm braw's wind direction improves the external member that generates heat and to the heating efficiency in appointed region.

The above-mentioned embodiments only represent some embodiments of the present invention, and the description thereof is more specific and detailed, but not to be construed as limiting the scope of the present invention. It should be noted that, for those skilled in the art, without departing from the spirit of the present invention, several variations and modifications can be made, which are within the scope of the present invention. Therefore, the protection scope of the present invention should be subject to the appended claims.

Claims (10)

1. An air duct interface structure, comprising:

the connector comprises a connector body and a protective shell, wherein one end of the connector body is communicated with an external air pipe, the other end of the connector body is communicated with the protective shell, and a plurality of avoiding holes are formed in the side wall of the protective shell; and

the heating external member comprises an annular shell and a plurality of heaters, the heaters are sequentially stacked in the annular shell, in one heater, the heater comprises a semiconductor heating element, a positive conductive terminal, a negative conductive terminal, a plurality of radiating fin top sheets and a plurality of radiating fin bottom sheets, the semiconductor heating element is arranged in the annular shell, each heat dissipation fin top sheet is arranged on one side surface of the semiconductor heating element, and a space is arranged between every two adjacent heat dissipation fin top sheets, each heat dissipation fin bottom sheet is arranged on one side surface of the semiconductor heating element far away from each heat dissipation fin top sheet, and a space is arranged between every two adjacent heat dissipation fin bottom sheets, the positive conductive terminal is connected with the heat dissipation fin top sheet positioned at the starting end, and the negative conductive terminal is connected with the heat dissipation fin bottom sheet positioned at the starting end.

2. The air hose interface structure of claim 1, wherein the interface kit further comprises a plurality of ribs, each rib being coupled to the interface tube and the protective shell, and each rib being adapted to abut a sidewall of the annular shell when the annular shell is nested within the protective shell.

3. An air hose interface structure according to claim 2, wherein said interface kit comprises 12 to 18 of said ribs.

4. The air hose interface structure of claim 1, wherein the interface kit further comprises a snap member, the snap member is disposed on an outer wall of the protective housing, the snap member is provided with a snap portion, and the snap member is used for the snap portion to snap the annular housing when the annular housing is embedded in the protective housing.

5. The air hose interface structure according to claim 4, wherein the protective housing is provided with a locking hole, the air hose interface structure further comprises a locking sleeve, the locking sleeve comprises a pressing member and a locking member, the pressing member is provided with a through hole, and when the locking member is used for clamping the annular housing by the fastening portion, the locking member penetrates through the through hole, so that the end portion of the locking member is screwed in the locking hole, and the pressing member presses and holds the protective housing.

6. The air hose interface structure of claim 1, further comprising a plurality of anti-touch panels, each anti-touch panel disposed within the interface tube body, and a space disposed between two adjacent anti-touch panels.

7. An air hose interface structure as in claim 6 wherein each said anti-touch plate is located adjacent an end of said interface tube body.

8. An air hose interface structure as in claim 1 wherein the interface tube and the protective shell are of unitary construction.

9. The air duct interface structure of claim 1, wherein the conductive terminal and the negative conductive terminal are both provided with flow guide holes.

10. The air hose interface structure of claim 9, wherein the deflector holes are circular holes.

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