CN213656032U - Integrated pipeline capable of quickly increasing room temperature - Google Patents

Abstract

The application relates to an integrated pipeline for rapidly increasing room temperature, which comprises two heat distribution pipelines arranged in a workshop trench side by side and a heat insulation shell for covering the two heat distribution pipelines simultaneously, wherein a heat insulation layer covers the outer surface of the heat insulation shell; the section of thermal-insulated casing inner chamber is "Y" font, and two thermal power pipeline are located one of thermal-insulated casing branch respectively, just the tip of two last branches of thermal-insulated casing department all is equipped with the air outlet, the tip of the lower branch department of thermal-insulated casing is equipped with the air intake, the inner chamber lower part of thermal-insulated casing is equipped with the fan of blowing, the wind direction of the fan of blowing is supreme and blow to from down the thermal power pipeline. This application has the effect of promoting the room temperature fast.

Description

Integrated pipeline capable of quickly increasing room temperature

Technical Field

The application relates to the field of warming equipment, in particular to an integrated pipeline for quickly improving room temperature.

Background

The coating process has very high requirements on the working environment of a coating workshop, and in winter, due to the indoor and outdoor ventilation coefficients of 6-12 times/h required by the coating process, the room temperature of the coating workshop is lower after ventilation is finished, so that the room temperature can be increased to the proper temperature only by needing a longer heating time, and the coating quality in the longer heating time is difficult to ensure.

Therefore, a temperature raising device is needed to quickly raise the room temperature of the coating workshop to ensure stable coating quality.

SUMMERY OF THE UTILITY MODEL

In order to promote the room temperature in painting shop fast, this application provides a promote integrated pipeline of room temperature fast.

The application provides a promote integrated pipeline of room temperature fast adopts following technical scheme:

an integrated pipeline for rapidly increasing the room temperature comprises two heat distribution pipelines arranged in a workshop trench side by side and a heat insulation shell for covering the two heat distribution pipelines simultaneously, wherein a heat insulation layer covers the outer surface of the heat insulation shell; the section of thermal-insulated casing inner chamber is "Y" font, and two thermal power pipeline are located one of thermal-insulated casing branch respectively, just the tip of two last branches of thermal-insulated casing department all is equipped with the air outlet, the tip of the lower branch department of thermal-insulated casing is equipped with the air intake, the inner chamber lower part of thermal-insulated casing is equipped with the fan of blowing, the wind direction of the fan of blowing is supreme and blow to from down the thermal power pipeline.

By adopting the technical scheme, hot water from a boiler room is introduced into the heat distribution pipeline, and heat emitted by the heat distribution pipeline is transferred into air in a narrow cavity in the heat insulation shell, so that the air in the heat insulation shell is hot air, and then the hot air is obliquely discharged to the vicinity of the ground of a workshop through the inclined upper branch of the Y-shaped heat insulation shell by the blowing fan so as to quickly spread to the vicinity of the ground of the whole workshop, and then the hot air is lighter and can rise, so that the large-range area in the workshop can be quickly heated; by arranging the combination of the Y-shaped heat insulation shell and the heat distribution pipeline, the heat transfer of the heat distribution pipeline and the guide discharge of the heat transfer air by the Y-shaped heat insulation shell are utilized, so that the hot air can be rapidly diffused and spread to most areas of a workshop, and the room temperature in the workshop is rapidly raised; and the blowing fan hidden in the workshop trench can reduce the noise caused by overlarge wind power so as to reduce the influence on workers.

Optionally, the heat insulation shell and the heat distribution pipeline are arranged in a through manner, the number of the blowing fans is multiple, and the blowing fans are uniformly distributed along the length direction of the heat insulation shell; the middle part of the heat insulation shell is provided with a plurality of avoidance areas which vertically penetrate through the heat insulation shell, and the avoidance areas and the blowing fan are arranged at intervals in the length direction of the thermal pipeline.

By adopting the technical scheme, the hot air in the heat insulation shell can be uniformly and completely discharged into a workshop as much as possible; and the avoidance area is arranged to ensure that cold air settled from the workshop floor can flow into the workshop trench, so that the cold and hot air circularly flows.

Optionally, the drift diameter of the avoidance region gradually increases from top to bottom.

By adopting the technical scheme, when cold air flows into the avoidance area, due to the change of the drift diameter of the avoidance area, the cold air suddenly expands, namely the section of the sound wave of the cold air suddenly changes suddenly on the expanded and contracted gas flow channel, so that the acoustic impedance in the drift diameter changes suddenly, the propagation direction of the sound wave is changed, reflection and interference occur in the avoidance area, and the noise reduction effect is achieved.

Optionally, an air guide member is disposed at a port of an upper branch of the heat insulation casing, the air guide member includes an upper air guide plate horizontally disposed and a lower air guide plate vertically disposed, the upper air guide plate and the lower air guide plate are both arranged in a length direction of the heat distribution pipeline, one side of each of the upper air guide plate and the lower air guide plate is connected to an inner wall of the upper branch of the heat insulation casing, and a space through which the air of the blowing fan passes is formed between a free side of the upper air guide plate and a free side of the lower air guide plate.

By adopting the technical scheme, the air guide piece is arranged to guide hot air, so that the hot air is diffused to the ground of a workshop along the horizontal direction as far as possible, and the narrow space can play a role in improving the flow rate of the hot air and improve the diffusion range; and the positions of the upper air deflector and the lower air deflector are arranged, an included angle area is formed between the upper air deflector and the upper branch inner wall of the heat insulation shell respectively, and the included angle area can be used for storing sundries falling into the heat insulation shell accidentally from the outside, namely, the situation that the heat insulation shell is blocked by the external sundries is reduced.

Optionally, the free side of the upper air deflector is higher than the free side of the lower air deflector.

By adopting the technical scheme, the situation that external impurities enter through the gap between the upper air deflector and the lower air deflector is further reduced.

Optionally, the upper air deflector and the lower air deflector are detachably connected to the heat insulation casing along the extending direction of the upper branch of the heat insulation casing.

By adopting the technical scheme, sundries in the included angle area can be taken out along the trend when the upper air deflector and the lower air deflector are convenient to disassemble.

Optionally, the heat distribution pipelines in two adjacent workshop ditches are connected through a connecting pipeline.

Through adopting above-mentioned technical scheme, realize linking to each other of heating power pipeline in the trench of many workshops.

Optionally, the outer wall of the connecting pipeline is wrapped with a heat insulation sleeve.

Through adopting above-mentioned technical scheme, reduce the loss of connecting tube department heat.

In summary, the present application includes at least one of the following beneficial technical effects:

by arranging the combination of the Y-shaped heat insulation shell and the heat distribution pipeline, the heat transfer of the heat distribution pipeline and the guide discharge of the heat transfer air by the Y-shaped heat insulation shell are utilized, so that the hot air can be rapidly diffused and spread to most areas of a workshop, and the room temperature in the workshop is rapidly raised;

by arranging the avoidance area, the circulating flow of cold and hot air can be formed, and the noise reduction effect is achieved;

through setting up the air guide, play the guide effect to the hot-air for along horizontal direction diffusion to workshop ground as far as possible, and narrow and small interval can play the effect that improves hot air flow rate, improves the diffusion scope, and then improves indoor rate of rise of temperature.

Drawings

Fig. 1 is a schematic view of the overall structure of the present embodiment.

Fig. 2 is a sectional view of the present embodiment for embodying the internal structure of the heat insulating casing.

Fig. 3 is a sectional view of the present embodiment for embodying the avoidance region.

Fig. 4 is a partially enlarged view of a portion a in fig. 2.

Description of reference numerals: 1. a thermal conduit; 2. a thermally insulated housing; 3. connecting a pipeline; 4. an air guide member; 10. a workshop trench; 101. a support; 21. an upper branch; 211. an air outlet; 212. a chute; 22. a lower branch; 221. an air inlet; 23. an avoidance area; 24. a blower fan; 31. a thermal insulation sleeve; 41. an upper air deflector; 42. a lower air deflector; 43. a first inclined plate; 44. a second inclined plate; 441. a slider; 45. an arc-shaped rod.

Detailed Description

The present application is described in further detail below with reference to figures 1-4.

The embodiment of the application discloses integrated pipeline for rapidly increasing room temperature. Referring to fig. 1, the system comprises two heat pipelines 1 which are arranged in a workshop trench 10 side by side, wherein the heat pipelines 1 are filled with hot water from a factory boiler room; the heating power pipelines 1 in the two adjacent workshop ditches 10 are connected through a connecting pipeline 3, the outer wall of the connecting pipeline 3 is wrapped with a heat insulation sleeve 31, and the heat insulation sleeve 31 is made of polyurethane heat insulation materials.

As shown in fig. 1, two adjacent heat distribution pipelines 1 are covered with a heat insulation housing 2, the heat insulation housing 2 is fixed in a workshop trench 10 through a bracket 101, and the outer surface of the heat insulation housing 2 is covered with a heat insulation layer (not shown in the figure) which is formed by coating aluminum silicate composite heat insulation paint and is used for reducing heat loss and waste of the heat distribution pipelines 1.

As shown in fig. 2, the heat insulation casing 2 is disposed along the entire length of the heat distribution pipe 1, the cross section of the heat insulation casing 2 is "Y" shaped, that is, the heat insulation casing 2 has two upper branches 21 inclined outward and a lower branch 22 vertical downward, the two heat distribution pipes 1 are respectively located in one upper branch 21, that is, the heat generated by the heat distribution pipe 1 is transferred to the air in the narrow inner cavity of the heat insulation casing 2, thereby forming hot air.

As shown in fig. 3, a plurality of avoidance areas 23 are arranged in the middle of the heat insulation shell 2, and the avoidance areas 23 are arranged at intervals along the length direction of the heat distribution pipeline 1; the avoidance area 23 vertically penetrates through the heat insulation shell 2, and the drift diameter of the avoidance area 23 is gradually increased from top to bottom.

As shown in fig. 2, an air inlet 221 is provided at the bottom surface of the lower branch 22 of the heat insulating case 2, and a plurality of blowing fans 24 are provided in the lower branch 22, and each blowing fan 24 and each escape area 23 are provided at intervals in the longitudinal direction of the heat insulating case 2. An air outlet 211 is arranged on the end surface of the upper branch 21 of the heat insulation shell 2, and the air outlet 211 is in a strip shape arranged along the length direction of the heat distribution pipeline 1.

Cold air settled on the workshop floor can flow into the workshop trench 10 through the avoidance area 23, so that the circulation of the air in the workshop trench 10 and the external air is realized; then through the fan 24 of blowing, the hot-air that continues to heat pipeline 1 is followed the slope of the thermal-insulated casing 2 of Y shape and is gone up branch 21 to the angle of slope is arranged near the workshop ground, makes it creep near whole workshop ground fast, then because hot-air self is lighter to can rise, make this hot-air can the rapid diffusion creep to the most region in workshop, and then to the rapid heating up in the workshop.

In order to increase the diffusion speed of the hot air, as shown in fig. 4, an air guide 4 is disposed at a port of the upper branch 21 of the heat insulation casing 2, the air guide 4 includes an upper air guide plate 41 horizontally disposed and a lower air guide plate 42 vertically disposed, the upper air guide plate 41 is higher than the lower air guide plate 42, and a ventilation gap is formed between edges of the upper air guide plate 41 and the lower air guide plate 42, that is, the hot air passing through the heat distribution pipeline 1 can be obliquely discharged by guiding of the air guide 4, and a narrow gap between the upper air guide plate 41 and the lower air guide plate 42 can play a role of contracting the hot air to a certain extent, so as to increase the flow speed of the hot air when passing through, thereby increasing the diffusion speed of the hot air, and increasing the temperature rise rate.

As shown in fig. 4, a first inclined plate 43 is fixed to one side of the upper air guiding plate 41, an upper surface of the first inclined plate 43 is attached to an upper inner wall of the upper branch 21, and an included angle area is formed between a lower surface of the first inclined plate 43 and an upper surface of the upper air guiding plate 41.

A second inclined plate 44 is fixed on one side of the lower air deflector 42, the surface of the second inclined plate 44 is attached to the lower inner wall of the upper branch 21, and an included angle area is formed between the opposite surfaces of the second inclined plate 44 and the lower air deflector 42; and an arc-shaped rod 45 is jointly connected and fixed between the first inclined plate 43 and the second inclined plate 44.

The back of the second inclined plate 44 is provided with a sliding block 441 in a protruding manner, the inner wall of the upper branch 21 is provided with a sliding groove 212 along the extending direction of the inner wall, and the air guide member 4 and the upper branch 21 can be quickly disassembled and assembled through the matching of the sliding block 441 and the sliding groove 212.

The included angle area is used for storing sundries accidentally falling into the heat insulation shell 2 from the outside, namely, the situation that the heat insulation shell 2 is blocked by the external sundries is reduced, the upper air deflector 41 and the lower air deflector 42 can be taken out of the heat insulation shell 2 together by pulling the arc-shaped rod 45, the sundries in the included angle area can be taken out conveniently and quickly.

The above embodiments are preferred embodiments of the present application, and the protection scope of the present application is not limited by the above embodiments, so: all equivalent changes made according to the structure, shape and principle of the present application shall be covered by the protection scope of the present application.

Claims (8)

1. An integrated pipeline for rapidly raising room temperature, which is characterized in that: the heat insulation device comprises two heat distribution pipelines (1) arranged in a workshop trench (10) side by side and a heat insulation shell (2) used for covering the two heat distribution pipelines (1) at the same time, wherein a heat insulation layer covers the outer surface of the heat insulation shell (2); the section of thermal-insulated casing (2) inner chamber is "Y" font, and two thermal power pipeline (1) are located one of thermal-insulated casing (2) respectively and go up branch (21), just the tip of branch (21) department all is equipped with air outlet (211) on two of thermal-insulated casing (2), the tip of the lower branch (22) department of thermal-insulated casing (2) is equipped with air intake (221), the inner chamber lower part of thermal-insulated casing (2) is equipped with the fan of blowing (24), the wind direction of the fan of blowing (24) is from supreme and blow to down thermal power pipeline (1).

2. The integrated duct for rapidly elevating room temperature according to claim 1, wherein: the heat insulation shell (2) and the heat distribution pipeline (1) are arranged in a through manner, a plurality of air blowing fans (24) are arranged, and the air blowing fans (24) are uniformly distributed along the length direction of the heat insulation shell (2); the middle part of the heat insulation shell (2) is provided with a plurality of avoidance areas (23) which vertically penetrate through the heat insulation shell, and the avoidance areas (23) and the blowing fans (24) are arranged at intervals along the length direction of the heat distribution pipeline (1).

3. The integrated duct for rapidly elevating room temperature according to claim 2, wherein: the drift diameter of the avoiding area (23) is gradually increased from top to bottom.

4. The integrated duct for rapidly elevating room temperature according to claim 1, wherein: the heat insulation type air conditioner is characterized in that an air guide piece (4) is arranged at a port of an upper branch (21) of the heat insulation shell (2), the air guide piece (4) comprises an upper air guide plate (41) and a lower air guide plate (42) which are horizontally arranged, the upper air guide plate (41) and the lower air guide plate (42) are arranged in a length mode and communicated with the heat distribution pipeline (1), one side of the upper air guide plate (41) and one side of the lower air guide plate (42) are connected with the inner wall of the upper branch (21) of the heat insulation shell (2), and a space for allowing air of the blowing fan (24) to pass through is formed between the free side of the upper air guide plate (41) and the free side of the lower air guide plate (42).

5. The integrated duct for rapidly elevating room temperature according to claim 4, wherein: the free side of the upper air deflector (41) is higher than the free side of the lower air deflector (42).

6. The integrated duct for rapidly elevating room temperature according to claim 5, wherein: the upper air deflector (41) and the lower air deflector (42) are detachably connected with the heat insulation shell (2) along the extending direction of the upper branch (21) of the heat insulation shell (2).

7. The integrated duct for rapidly elevating room temperature according to claim 1, wherein: the heat distribution pipelines (1) in the two adjacent workshop ditches (10) are connected through a connecting pipeline (3).

8. The integrated duct for rapidly elevating room temperature as claimed in claim 7, wherein: the outer wall of the connecting pipeline (3) is wrapped with a heat insulation sleeve (31).

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