KR101876547B1 - A refrigeration pipe with defrost function - Google Patents

Abstract

The present invention relates to a refrigeration pipe with a defrost function, which includes: a pipe body provided at an upper portion thereof with an upper inclined part in a triangular-tubular shape having an opened lower portion and a pointed upper portion and provided at a lower portion thereof with a lower semicircular part in a semicircular-tubular shape having an opened upper portion, in which the upper inclined part and the lower semicircular part are integrally formed in one tube member to communicate with each other in the vertical direction in order to circulate a refrigerant therein; an upper heat conductive fin protruding vertically upward in the longitudinal direction on an upper end of an outer side surface of the upper inclined part; a lateral inclined heat conductive fin protruding on both left and right sides of an outer side of the lower semicircular part so as to be inclined outwardly downward along the longitudinal direction, and having a slope larger than or equal to a slope of the upper inclined part with respect to a horizontal axis; a plurality of lower heat conductive fins protruding downward along the longitudinal direction at a lower portion of the outer side surface of the lower semicircular part; lateral upper internal heat conductive fin protruding toward a center of the pipe body along the longitudinal direction on both left and right sides of an inner side surface of the upper inclined part, and forming a holding space so that hot gas supplied to the inside of the pipe body during a defrosting process is concentrated on the inner upper portion of the pipe body; and a plurality of lower inner heat conductive fins formed radially along the longitudinal direction on the inner surface of the lower semicircular part.

Description

A refrigeration pipe with defrost function "

BACKGROUND OF THE INVENTION 1. Field of the Invention [0001] The present invention relates to a freezing pipe installed in various refrigeration equipments and circulating a low-temperature refrigerant to cool outside air to be kept in a frozen state. More particularly, the present invention relates to a freezing pipe having a triangular- And a lower semicircular portion having a semicircular tube shape with an upper portion opened at its lower portion. The upper inclined portion and the lower semicircular portion are formed to communicate with each other in an upper and lower direction, A lower heat transfer fin protruding in a longitudinal direction at an upper end portion of an outer side surface of the upper sloping portion and a lower heat transfer fin protruding outwardly downwardly along a longitudinal direction at both sides of the outer side surface of the lower semi- A slope equal to or larger than the slope of the upper slope portion with respect to the horizontal axis A plurality of lower end heat transfer fins protruding downward along the longitudinal direction at the lower side of the outer side surface of the lower semicircular portion and protruding toward the center of the pipe body along the longitudinal direction on both left and right sides of the inner side surface of the upper slope portion, The upper and lower inner heat transfer fins forming a stay space so that the hot gas supplied to the inner side of the pipe body during the defrosting process is concentrated on the inner upper side of the pipe body; And a plurality of lower inner heat conductive fins formed on the lower inner heat conductive fins.

Generally, the refrigeration system is a facility for cooling the evaporator by utilizing the latent heat of evaporation of the refrigerant to cool the evaporator, and it comprises a compressor, a condenser, an expansion valve and an evaporator, and the compressor compresses the circulating refrigerant, The refrigerant is compressed to a high temperature and a high pressure to move to the condenser. The condenser absorbs the heat of the high-temperature and high-pressure refrigerant by using water or air, and the refrigerant is condensed and liquefied And the expansion valve is converted into a low temperature and a low pressure by the throttling action while the condensed liquefied refrigerant passes through the expansion valve and is sent to the evaporator. In the evaporator, the refrigerant of low temperature and low pressure evaporates and absorbs the surrounding heat And then flows into the compressor again to be circulated, thereby constituting a refrigeration cycle, In the refrigeration system, the condenser and the evaporator are connected to each other through a plurality of freezing pipes so that heat exchange is performed during passage of the low-temperature and low-pressure refrigerant. The conventional freezing pipe is simply a hollow circular pipe, There is a problem that the heat exchange efficiency due to the contact is greatly lowered.

As a conventional technique for solving the problems related to the conventional refrigeration pipe as described above, Korean Utility Model Laid-Open Publication No. 20-1999-0012446 discloses a pipe for a cooling device, in which a pipe And a pair of projections for elevating the heat transfer surface in the axial direction are provided on the inner circumference and a pair of fins are provided so as to correspond to each other in the longitudinal direction of the outer periphery.

However, in the above-mentioned prior art, the protrusions formed on the inner circumferential surface of the pipe are formed in a serpentine shape with a short length, so that the contact area with the coolant flowing in the pipe is not large and the heat exchange efficiency through the protrusions is low. And a pair of fins are protruded on both sides of the outer periphery. Thus, in the course of the heat exchange through the refrigerant passing through the outer periphery, the gaps adhered to the outer circumferential surface of the pipe are accumulated thicker on the upper portion of the pipe, In the defrosting process for reducing the cooling efficiency due to the blockage of the cold air due to the lumps and for supplying hot gas heated to a certain temperature to the inside of the pipe to remove the lumps adhering to the outer circumferential surface of the pipe, It is caught by a pair of pins protruding from the outer periphery and does not flow downward There is a problem in that the operator in the operator gender loaf falling from a pipe installed in a high position in such a way the defrost process by hand was a problem that preside manually break the lumps gender as the accident frequently occurs right.

SUMMARY OF THE INVENTION The present invention has been made to solve the above problems, and it is an object of the present invention to provide a pipe body having an upper inclined portion in the form of a triangular pipe and a lower semicircular portion in a lower semicircular tube shape, And left and right tapered heat transfer fins are protruded from the left and right sides of the outer side surface of the lower semicircular part so as to be inclined downward outward so that the lump of gaseous matter attached to the upper part of the outer circumferential surface of the pipe body during the defrosting operation by the hot gas supplied to the inside of the pipe body And the left and right upper side inner heat conductive fins are protruded toward the central portion of the pipe body at both sides of the inner side of the upper slanted portion so as to protrude toward the center of the pipe body. So that a stay space is formed in the upper portion of the inside of the pipe body As it is an object to which the hot gas to be supplied to the inside of the pipe body in the defrosting process, the height of the removal efficiency of the mass sex to ensure focus on the inner upper portion of the pipe body is attached to the outer surface of the upper inclined portion.

In order to achieve the above object, the upper part is provided with a lower half-circle part having a semicircular tube-like shape with an upper portion opened and an upper part having a triangular pipe-shaped upper inclined part and an upper part opened at the lower part, wherein the upper inclined part and the lower half- And a lower heat transfer fin protruding from the upper end of the upper side of the upper side of the upper side in the longitudinal direction along the longitudinal direction of the upper side heat transfer fin, Left and right side inclined heat transfer fins protruding from both sides in the longitudinal direction and inclined downward in the longitudinal direction and having a slope equal to or larger than the slope of the upper slope portion with respect to the horizontal axis, A plurality of lower end heat transfer fins protruding downward along the longitudinal direction, The upper and lower inner heat conductive fins are formed so as to protrude toward the central portion of the pipe body along the longitudinal direction on both lateral sides of the inner side surface and form a stay space so that hot gas supplied to the inner side of the pipe body in the defrosting process is concentrated on the inner upper side of the pipe body. And a plurality of lower inner heat conductive fins radially formed on the inner surface of the lower semicircular portion at regular intervals along the longitudinal direction.

As described above, according to the present invention, there is provided a pipe body having an upper slope part in the form of a triangular pipe and a lower semicircular part in the form of a semicircular tube in the lower part, an upper heat conductive fin protruding vertically upward from the upper side of the outer side of the upper slope part, Left and right side inclined heat conductive fins are protruded to be inclined downward outwardly on the left and right sides of the outer side surface of the semicircular part so that the lumps adhering to the upper part of the outer peripheral surface of the pipe body during the defrosting operation by the hot gas supplied to the inside of the pipe body Right and left side inclined heat conductive fins, and left and right upper side inner heat conductive fins protrude toward the central portion of the pipe body on both sides of the inner side of the upper slanted portion The upper left and right upper inner heat conductive fins are provided on the inner upper side of the pipe body, It is formed by it is possible to improve the removal efficiency of the mass gender attached to the outer surface of the upper inclined portion as the hot gas supplied to the inside of the pipe body in the defrosting process, concentrating on the inside upper portion of the pipe body.

1 is a perspective view schematically showing an installation state of a freezing pipe according to the present invention;
2 is a front schematic view of a refrigeration pipe according to the present invention;
3 is a schematic cross-sectional view showing a retention path of a hot gas supplied to remove a lump of glaze attached to the upper part of the outer circumferential surface of the freezing pipe according to the present invention
FIG. 4 is a front schematic view showing a state in which heater insertion holes are formed on both left and right sides of the outer side of the lower semicircular portion of the freezing pipe according to the present invention,
5 is a front schematic view of a refrigerator pipe according to the present invention in which a heater mounting groove is formed in a lower portion of an outer side of a lower half-
6 is a perspective view of a refrigeration pipe according to another embodiment of the present invention;

Hereinafter, preferred embodiments of the present invention will be described in detail with reference to the drawings.

As shown in FIGS. 1 to 6, the refrigeration pipe 1 having the defoaming function of the present invention is installed in a refrigeration facility such as various refrigeration warehouses, and the low temperature refrigerant is circulated therein, And a lower semicircular part (4) having a semicircular tube shape with an upper part opened at its lower part is provided at the upper part, and a lower semicircular part The inclined portion 3 and the lower semicircular portion 4 are formed so as to communicate with each other in an upper portion and lower portion so as to form a single pipe body to circulate the refrigerant therein. A lower heat transfer fin 5 protruding vertically upward along the longitudinal direction of the lower semicircular part 4 and a lower heat transfer fin 5 projecting outwardly downward along the longitudinal direction on both left and right sides of the outer surface of the lower semicircular part 4, Side slant heat transfer fins 10 formed so as to have a slope equal to or larger than the slope of the upper sloped portion 3 and a plurality of lower sloped heat transfer fins 10 projecting downward along the longitudinal direction at the lower side of the outer side of the lower semi- The heat transfer fins 11 are provided on both sides of the inner side surface of the upper slope part 3 and protrude toward the central part of the pipe body 2 along the longitudinal direction and are supplied to the inside of the pipe body 2 in the defrosting process Left and right upper internal heat transfer fins 12 forming a stay space 13 such that the hot gas is concentrated on the inside upper part of the pipe body 2 and an inner heat transfer fin 12 formed on the inner side surface of the lower semi- And a plurality of lower inner heat conductive fins 15 formed radially.

The freezing pipe 1 is made of a metal such as aluminum or aluminum alloy as a whole, and is made of a material having high thermal conductivity and corrosion resistance.

As shown in FIGS. 1 to 5, the pipe body 2 has a hollow tube shape, and a refrigerant passes through the inside of the pipe body 2 to exchange heat with the outside air to perform a refrigerating operation. The upper portion has a lower triangular opening, The upper half portion 4 and the lower half portion 4 are integrally formed by a tubular upper sloping portion 3 and a lower portion formed with a semicircular tube- And the refrigerant is circulated inside the tube body, and when the refrigerating operation is performed by circulation of the refrigerant for a certain period of time, the refrigerant is adhered to the outer circumferential surface of the pipe body 2 to form a lump of gaseous body.

As described above, defrosting operation using waste heat (hot gas) of the refrigeration cycle is performed in order to prevent deterioration of the heat transfer effect due to the agglomerate on the outer circumferential surface of the pipe body 2, 2 is formed by the upper slope part 3 having a triangular tube shape with an opening at its lower end and the lumps attached to the upper side of the outer side surface of the upper slope part 3 are adhered to the lump Side surface of the upper sloping portion 3 due to the weight of the lump of the casting while being easily melted. Thus, the degaussing time is shortened by the upper sloping portion 3, The work is not necessary, and the safety is removed.

As shown in FIGS. 1 to 3, the upper heat transfer fin 5 is formed to be vertically upwardly projected along the longitudinal direction in a straight line on the upper end of the outer side surface of the upper slope 3, The lump attached to the upper side of the outer side surface of the upper sloped portion 3 by the upper heat transfer fin 5 is divided into left and right portions during the defrosting operation by the hot gas, A plurality of ring fastening holes 6 are formed in the upper heat conductive fins 5 at regular intervals so that the ring fastening holes 6 are fastened to the fastening rings 6 having an "S" shape or the like 7 so that the pipe body 2 can be easily installed in a state where it is caught by the installation pipe 8.

The upper inclined portion 3 has a central heat conductive fins 9 protruding vertically downward along the longitudinal direction in a straight line on the upper end portion of the inner side surface so that the central heat conductive fins 9 and the upper heat conductive fins 5 So that the heat exchange efficiency of the freezing pipe 1 is increased.

As shown in FIGS. 1 to 3, the left and right tilting heat conductive fins 10 are protruded from the left and right sides of the outer side of the lower semi- ) Is prevented from continuing to the lower semicircular part (4) so as to prevent the lump of glaze from adhering to the outer circumferential surface of the pipe body (2) in one lump state, wherein the left and right slopes The heat conductive fins 10 are formed so as to be linearly symmetrical with respect to each other and have a slope equal to or larger than the slope of the upper slope 3 with respect to the horizontal axis, The left and right tapered heat conductive fins 10 are formed in a bent state downward so that the lumps of the melted adhesive surface naturally flow down and are removed by the self weight during the defrosting operation by the hot gas And the outer heat transfer area of the freezing pipe 1 is increased by the left and right tilted heat conductive fins 10 so that the refrigerating efficiency is improved.

On the other hand, when the left and right slant heat transfer fins 10 are protruded at a gentle slope than the slope of the upper slant portion 3, the left and right slant heat conductive fins 10 are formed in the lower end portion of the upper slant portion 3 upward It is formed in a bent state and the lump of the casting is caught in the bent portion, so that the lump of the cast remains in the casting even when the defoaming operation is performed by the hot gas.

1 to 5, the lower heat transfer fin 11 is formed so as to extend in a straight line along the longitudinal direction at a lower portion of the outer side surface of the lower semicircular portion 4, and has a plurality of lower ends The heat transfer fins 11 are formed to be protruded downward with a predetermined spacing so that the external heat transfer area of the freezing pipe 1 is increased by the plurality of the lower heat transfer fins 11 to greatly improve the refrigerating efficiency.

As shown in FIGS. 1 to 3, the left and right upper inner heat conductive fins 12 are protruded toward the central portion of the pipe body 2 in a straight line along the longitudinal direction on both left and right sides of the inner side surface of the upper slanted portion 3 The hot gas supplied to the inside of the pipe body 2 during the defrosting process is formed so as to concentrate on the inside upper part of the pipe body 2 and the left and right upper internal heat conductive fins 12 As shown in FIG. 3, each of the upper and lower inner heating fins 12 is formed with an extended bending portion 14, The hot gas supplied in the defrosting process is concentrated on the inner upper portion of the pipe body 2 and the upper sloping portion 3 is heated to a higher temperature to remove the hot gasses from the slag attached to the upper outer surface of the upper sloping portion 3 The transferred heat is transferred to the mounting surface Is dissolved in a short time gender lump is to be down easily removed flows downward along the slope.

1 to 5, the lower inner heat conductive fins 15 are formed on the inner surface of the lower semicircular portion 4 in a straight line along the longitudinal direction, The heat transfer fins 11 are radially protruded so that the internal heat transfer area of the freezing pipe 1 is increased by the plurality of the lower internal heat transfer fins 15 so that the refrigerating efficiency is greatly improved.

4, the lower half-circle portion 4 has heater insertion holes 16 through which a conventional electrothermal heater 17 is inserted through the left and right sides of the outer surface, respectively, in the longitudinal direction of the freezing pipe 1 The heater insertion hole 16 is formed between the left and right slant heat transfer fins 10 and the lower semicircular portion 4 so that heat from the heat transfer heater 17 is transmitted to the left and right slant heat transfer fins 10 So that the adhered surface of the agglomerate adhering to the upper surface portion of the left and right inclined heating fins 10 is quickly melted and dropped.

5, the lower semicircular portion 4 is formed with a heater mounting groove 18 in which a conventional electrothermal heater 17 is inserted and formed along the longitudinal direction of the freezing pipe 1, The heat transfer heater 17 is inserted into the heater mounting groove 18 through a lower portion of the lower portion of the heater mounting groove 18 which is opened in a pocket shape and the heat transferred from the heat transfer heater 17 is transferred to the lower semi- 4), and is rapidly melted and removed.

6, the upper part of the freezing pipe 1 according to the present invention is provided with an upper sloped portion 3 having a triangular-tube shape with an open bottom and a top portion, The upper slope part 3 and the lower semicircular part 4 are formed so as to communicate with each other in an upper part and a lower part so as to form a single pipe and circulate the refrigerant through the pipe. A lower heat transfer fin 5 protruding vertically upward in the longitudinal direction at an upper end portion of an outer side surface of the upper slope portion 3; A plurality of lower end heat transfer fins 11 protruding downwardly from both sides of the upper side inclined portion 3 and extending in the longitudinal direction on both left and right sides of the inner side surface of the upper side inclined portion 3 toward the central portion of the pipe body 2, Bent The upper and lower inner heat conductive fins 14 and the upper inner heat conductive fins 14 are formed so that the hot gas supplied to the inside of the pipe body 2 in the defrosting process is concentrated on the inner upper side of the pipe body 2, 12 and a plurality of lower inner heat conductive fins 15 radially formed on the inner surface of the lower semicircular portion 4 at regular intervals along the longitudinal direction.

Hereinafter, the operation of the present invention will be described.

When the refrigeration pipe 1 having the defrosting function according to the present invention is installed in a refrigeration facility such as various refrigeration warehouses and the refrigerant of low temperature is circulated inside and the outside air is cooled to be kept in a frozen state, The refrigerant pipe 1 is attached to the outer circumferential surface of the refrigerant pipe 1 by heat exchange with the refrigerant passing through the inside of the refrigerant pipe 1, In this case, the defrosting operation using the waste heat (hot gas) of the refrigeration cycle is performed. In this case, as shown in FIG. 3, The hot gas supplied to the inside of the freezing pipe 1 in the defrosting process is supplied to the upper inclined portion 3 by the left and right upper side heat transfer fins 12 formed on the inner side surface of the upper sloping portion 3 of the pipe body 2, The upper inclined portion 3 is heated to a higher temperature and the heat transferred from the agglomerate attached to the upper outer side of the upper inclined portion 3 is adhered to the upper portion of the upper inclined portion 3, The upper end portion of the upper slope portion 3 is vertically upwardly protruded from the upper end portion of the upper slope portion 3 during the defrosting operation by hot gas, The fins 5 are divided into left and right gaps to facilitate removal.

The left and right slant heat transfer fins 10 of the lower semicircular part 4 are inclined downwardly in a lower end portion of the upper slant part 3 so that when the defoaming operation by hot gas is performed, Of the pipe body (2) by the left and right tilting heat conductive fins (10) to the upper semicircular part (3) of the pipe body (2) (4) and prevents the outer peripheral surface of the pipe body (2) from being adhered in a single lump state so that the lumps in the defoaming operation can be removed more quickly.

1. Refrigeration pipe 2. Pipe body
3. Upper slope 4. Lower semicircular part
5. Upper heat pin 6. Ring tightening ball
7. Fastening ring 8. Installation pipe
9. Central heating pin 10. Tapered heating pin
11. Lower heat transfer pin 12. Upper internal heat transfer pin
13. Retention space part 14. Extension bending part
15. Lower inner heat transfer pin 16. Heater insertion hole
17. Electric heater 18. Heater mounting groove

Claims (5)

And a lower semicircular portion 4 having a semicircular tubular shape with an upper portion opened is provided at an upper portion thereof and an upper sloping portion 3 having an upper sloped portion 3 and an upper sloped portion 3 The semicircular part 4 has a pipe body 2 formed so as to communicate with the upper and lower parts integrally so as to form a single pipe and circulate the refrigerant therein and a pipe body 2 vertically upwardly The upper heat conductive fins 5 protrude from the lower semicircular portion 4 and are protruded outwardly downward along the longitudinal direction at both left and right sides of the outer surface of the lower semicircular portion 4, A plurality of lower end heat transfer fins 11 formed downwardly in the longitudinal direction below the outer side surface of the lower semicircular portion 4 and a plurality of lower end heat transfer fins 11 formed on the upper side slanting portion 3, On the left and right sides of the inner side of the room And the hot gas supplied to the inside of the pipe body 2 in the defrosting process is concentrated on the inner upper side of the pipe body 2, Side upper heat transfer fins 12 and a plurality of lower internal heat transfer fins 15 radially formed at an inner side surface of the lower semispherical portion 4 at regular intervals along the longitudinal direction, A plurality of ring fastening holes 6 are drilled at regular intervals to fasten the fastening rings 7 to the ring fastening holes 6 so that the pipe body 2 is fastened to the mounting pipe 8, Wherein the upper inner heat conductive fins (12) are each formed with an extended bending portion (14) which is bent in a horizontal direction at an end portion and extended by a predetermined length.
delete The refrigerator according to claim 1, wherein the lower semicircular part (4) has a heater insertion hole (16) through which an electrically heated heater (17) penetrates on both left and right sides of the outer side, along the longitudinal direction of the freezing pipe (1) Wherein the heater insertion hole (16) is formed between the left and right tapered heat conductive fins (10) and the lower semicircular part (4).
The refrigerator according to claim 1, wherein the lower semicircular part (4) is formed with a heater mounting groove (18) in which the electrothermal heater (17) is inserted in the lower part of the outer side surface along the longitudinal direction of the freezing pipe (1) Characterized in that the mounting groove (18) is inserted and mounted in the interior of the heat transfer heater (17) through a lower open lowered pocket.
And a lower semicircular part 4 in the form of a semicircular tube with an upper part opened at its lower part is provided at the upper part of the upper slope part 3, The lower semicircular part 4 has a pipe body 2 formed to communicate with the upper side and the lower side integrally so as to form a single pipe and circulate the refrigerant therein, A plurality of lower heat transfer fins 11 protruded downward along the longitudinal direction at a lower portion of the outer side of the lower semicircular portion 4 and a plurality of lower heat transfer fins 11 projecting downward from the inside of the upper slope portion 3, The pipe body 2 is protruded along the longitudinal direction on both lateral sides of the pipe body 2 while being bent in the horizontal direction at an end portion thereof so as to extend a predetermined length. Quot; hot " A pair of left and right upper side heat transfer fins 12 forming a stay space 13 so as to concentrate on the inside upper part of the pipe body 2, And a plurality of lower inner heat conductive fins (15) formed on the lower inner heat conductive fins (15).

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