CN212618909U - Device for improving efficiency of coil type ice storage, icing and deicing - Google Patents
Device for improving efficiency of coil type ice storage, icing and deicing Download PDFInfo
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- CN212618909U CN212618909U CN202020068053.8U CN202020068053U CN212618909U CN 212618909 U CN212618909 U CN 212618909U CN 202020068053 U CN202020068053 U CN 202020068053U CN 212618909 U CN212618909 U CN 212618909U
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Abstract
The utility model provides an improve device of coil pipe formula ice cold-storage ice-melting efficiency that freezes: comprises an ice storage tank; the ice storage tank is internally provided with an ice storage coil pipe, a left secondary refrigerant header, a right secondary refrigerant header, a left water distribution pipe header and a right water distribution pipe header; the left secondary refrigerant header and the right secondary refrigerant header are respectively positioned at the left side and the right side of the ice storage coil and are communicated with the ice storage coil; the left water distribution pipe header is positioned on the left side of the left secondary refrigerant header, and the right water distribution pipe header is positioned on the right side of the right secondary refrigerant header; the left water distribution pipe header is connected with the left water distribution pipe; the left secondary refrigerant header is communicated with an outlet of the ice storage coil pipe, and the right secondary refrigerant header is communicated with an inlet of the ice storage coil pipe; the utility model discloses can effectively improve the conical ice sheet that freezes the in-process and form for ice sheet thickness is even, thereby improves freezing efficiency.
Description
Technical Field
The utility model relates to a belong to warm logical air conditioner application, concretely relates to improve device of coil pipe formula ice cold-storage ice-freezing and ice-melting efficiency.
Background
Ice storage technology has been developed in recent years as an important energy storage technology. The ice cold accumulation is to store cold energy by using the phase change latent heat of ice, the ice is made by using electricity during the electricity consumption valley period to store the cold energy, and the stored cold energy is released to an air conditioning system to supply cold during the electricity consumption peak period, so that the peak shifting and valley filling of a power grid are realized, and the safe and efficient operation of the power grid is promoted. At present, coil-type ice storage tanks are mostly adopted in the ice storage technology, the ice making mode of the coil-type ice storage tanks is static ice making, and the ice melting is mainly carried out in the cold taking process. The external ice melting and cold taking process is that high-temperature chilled water is directly contacted with an ice layer to gradually melt the ice layer from outside to inside. When the ice storage tank is frozen, the temperature of the secondary refrigerant in the ice storage coil pipe changes along with the flowing path, the inlet temperature is low, the outlet temperature is high, and a conical ice layer is formed outside the coil pipe, namely the ice layer at the inlet is thick, the ice layer at the outlet is thin, and the ice layer is uneven and consistent in thickness, so that a dead zone is generated during ice melting, and the ice melting is delayed. When the ice is melted, the high-temperature chilled water flowing out of the water distributor slowly flows on the ice layer along the length direction of the coil pipe and continuously melts the ice layer from outside to inside. Because the temperature of the frozen water between the ice layers can change along with the slow flowing of the frozen water, the inlet temperature is high, the outlet temperature is low, the ice layers near the inlet can be melted first, the unmelted ice layers are approximately conical, and the ice layers at the outlet are thicker. The non-uniformity of ice layer melting can cause the flow distribution of the cold water to be non-uniform, and the efficiency of melting ice and cooling cold is reduced.
In order to ensure that icing and ice melting in the ice storage tank are uniform, an air stirrer is designed in the ice storage tank, air is introduced into the bottom of the ice storage tank, and a large number of bubbles rise through buoyancy to disturb water flow, so that the icing and the ice melting are uniform. However, the use of an air stirrer to deliver air into water for a long period of time will tend to make the water slightly acidic, accelerating the corrosion of the metal coils immersed in the water. Meanwhile, the bubbles can only disturb water at the upper and lower positions, cannot disturb water at the left and right positions (the positions of a chilled water inlet and outlet), and cannot improve the conical ice layer for icing and melting ice.
Accordingly, there is a need for improvements in the art.
SUMMERY OF THE UTILITY MODEL
The to-be-solved technical problem of the utility model is to provide an efficient improves device that coil pipe formula ice storage freezes ice-melt efficiency.
In order to solve the technical problem, the utility model provides an improve device of coil pipe formula ice cold-storage ice-melting efficiency that freezes: comprises an ice storage tank;
the ice storage tank is internally provided with an ice storage coil pipe, a left secondary refrigerant header, a right secondary refrigerant header, a left water distribution pipe header and a right water distribution pipe header;
the left secondary refrigerant header and the right secondary refrigerant header are respectively positioned at the left side and the right side of the ice storage coil and are communicated with the ice storage coil; the left water distribution pipe header is positioned on the left side of the left secondary refrigerant header, and the right water distribution pipe header is positioned on the right side of the right secondary refrigerant header; the left water distribution pipe header is connected with the left water distribution pipe;
the left secondary refrigerant header is communicated with an outlet of the ice storage coil pipe, and the right secondary refrigerant header is communicated with an inlet of the ice storage coil pipe;
the secondary refrigerant pipe is positioned at the outer side of the ice storage tank, the secondary refrigerant pipe is divided into two paths which extend into the ice storage tank from the outer side of the ice storage tank, one path is connected with the left secondary refrigerant header through the secondary refrigerant regulating valve I, the other path is connected with the right secondary refrigerant header through the secondary refrigerant regulating valve II,
the left secondary refrigerant header is connected with the secondary refrigerant outlet pipe through a secondary refrigerant regulating valve III, and the right secondary refrigerant header is connected with the secondary refrigerant outlet pipe through a secondary refrigerant regulating valve IV;
the air conditioner water return pipe is positioned outside the ice storage tank, the air conditioner water return pipe is divided into two paths which extend into the ice storage tank from the outside of the ice storage tank, one path is connected with the left water distribution pipe header through the chilled water regulating valve I, and the other path is connected with the right water distribution pipe header through the chilled water regulating valve II;
and the air-conditioning water supply pipe is respectively connected with the air-conditioning user side and the ice storage tank.
As right the utility model provides the improvement of the device of high coil pipe formula ice cold-storage ice-melting efficiency that freezes:
the inlet of a water supply pipe of the air conditioner is divided into two paths, one path is provided with a chilled water regulating valve III, and the chilled water regulating valve III extends into an ice storage groove right below the left side of the ice storage coil pipe and is communicated with the ice storage groove; and a fourth chilled water regulating valve is arranged on the other path and extends into the ice storage tank right below the right side of the ice storage coil pipe to be communicated.
As right the utility model provides the high coil pipe formula ice cold-storage icing ice-melt device of efficiency further improves:
the left water distribution pipe is provided with a plurality of spray holes at one side facing the ice storage coil pipe; the right secondary refrigerant header is connected with the right water distribution pipe, and the right water distribution pipe is provided with a plurality of spray holes on one side facing the ice storage coil pipe.
The utility model provides high coil pipe formula ice cold-storage ice-melt efficiency's device's technical advantage does:
1. the device has simple structure and flexible and convenient operation.
2. The conical ice layer formed in the icing process can be effectively improved, so that the thickness of the ice layer is uniform, and the icing efficiency is improved.
3. No matter in the process of freezing or in the process of melting ice, the flow direction can be repeatedly switched for many times, and the switching times are more, so that the effect is better.
Drawings
The following describes the present invention in further detail with reference to the accompanying drawings.
FIG. 1 is a schematic structural view of the device for improving the efficiency of the coil type ice storage, icing and thawing of the utility model;
fig. 2 is a sectional view in the direction a-a of the device for improving the efficiency of the coil type ice storage, icing and thawing of ice in fig. 1.
In the figure: the system comprises 1-secondary refrigerant pipe, 2-air conditioner water return pipe, 3-secondary refrigerant outlet pipe, 4-air conditioner water supply pipe, 5-6-chilled water regulating valve, 7-10-secondary refrigerant regulating valve, 11-left water distribution pipe header, 12-right water distribution pipe header, 13-left secondary refrigerant header, 14-right secondary refrigerant header, 15-left water distribution pipe, 16-right water distribution pipe, 17-ice storage coil pipe and 18-19-chilled water regulating valve.
Detailed Description
The invention will be further described with reference to specific examples, but the scope of the invention is not limited thereto.
Embodiment 1, a device for improving efficiency of coil type ice storage, icing and de-icing, as shown in fig. 1-2, comprises an ice storage tank.
The ice storage tank is provided with an ice storage coil 17, a left secondary refrigerant header 13, a right secondary refrigerant header 14, a left water distribution pipe header 11 and a right water distribution pipe header 12. The left coolant header 13 and the right coolant header 14 are located on and communicate with the left and right sides of the ice storage coil 17, respectively. The left water distribution header 11 is located on the left side of the left coolant header 13, and the right water distribution header 12 is located on the right side of the right coolant header 14. The left water distribution pipe header 11 is connected with a left water distribution pipe 15, and a plurality of spray holes are formed in the left water distribution pipe 15 at one side facing the ice storage coil 17; the right-side secondary refrigerant header 14 is connected with a right-side water distribution pipe 16, and a plurality of spray holes are formed in the right-side water distribution pipe 16 and face the ice storage coil 17.
The left coolant header 13 is in communication with the outlet of the ice storage coil 17 and the right coolant header 14 is in communication with the inlet of the ice storage coil 17.
The secondary refrigerant pipe 1 is positioned at the outer side of the ice storage tank, the secondary refrigerant pipe 1 is divided into two paths which extend into the ice storage tank from the outer side of the ice storage tank, one path is connected with the left secondary refrigerant header 13 through the secondary refrigerant regulating valve I9, the other path is connected with the right secondary refrigerant header 14 through the secondary refrigerant regulating valve II 10,
the left secondary refrigerant header 13 is connected with the secondary refrigerant outlet pipe 3 through a secondary refrigerant regulating valve III 7, and the right secondary refrigerant header 14 is connected with the secondary refrigerant outlet pipe 3 through a secondary refrigerant regulating valve IV 8.
The air conditioner water return pipe 2 is positioned outside the ice storage tank, the air conditioner water return pipe 2 is divided into two paths, the two paths extend into the ice storage tank from the outside of the ice storage tank, one path is connected with the left water distribution pipe header 11 through the chilled water regulating valve I5, and the other path is connected with the right water distribution pipe header 12 through the chilled water regulating valve II 6.
The air-conditioning water supply pipe 4 is divided into two paths, one path is provided with a chilled water regulating valve III 18, and the chilled water regulating valve III extends into an ice storage groove right below the left side of the ice storage coil 17 to be communicated; and the other path is provided with a chilled water regulating valve IV 19 which extends into the ice storage tank right below the right side of the ice storage coil 17 to be communicated.
The low-temperature chilled water flows out of the ice storage tank from the air conditioner water supply pipe 4 and flows into the air conditioner user side through the air conditioner water supply pipe 4.
The method for improving the efficiency of the coil type ice storage, icing and deicing comprises the following steps:
and (3) an icing process: and a fourth secondary refrigerant regulating valve 8 and a first secondary refrigerant regulating valve 9 are opened, a third secondary refrigerant regulating valve 7 and a second secondary refrigerant regulating valve 10 are closed, and a first chilled water regulating valve 5 and a second chilled water regulating valve 6 which are positioned on an air conditioner water return pipe, a third chilled water regulating valve 18 and a fourth chilled water regulating valve 19 which are positioned on an air conditioner water supply pipe are all in a closed state. The low-temperature secondary refrigerant prepared by the refrigerating unit enters the ice storage tank from the secondary refrigerant pipe 1 and flows into the ice storage coil 17 through the left secondary refrigerant header 13. The low-temperature secondary refrigerant exchanges heat with the water outside the pipe in the ice storage coil 17, the temperature is raised to form the high-temperature secondary refrigerant, and the water outside the pipe is gradually frozen due to being cooled to form an ice layer. The high-temperature secondary refrigerant flows out of the right secondary refrigerant header 14 through the ice storage coil 17 and flows back to the refrigerating unit through the secondary refrigerant outlet pipe 3 to form a secondary refrigerant loop. When the left and right inlet and outlet directions of the secondary refrigerant need to be switched, the secondary refrigerant regulating valve III 7 and the secondary refrigerant regulating valve II 10 are opened, the secondary refrigerant regulating valve IV 8 and the secondary refrigerant regulating valve I9 are closed, and the chilled water regulating valve I5 and the chilled water regulating valve II 6 on the air conditioner water return pipe, the chilled water regulating valve III 18 and the chilled water regulating valve IV 19 on the air conditioner water supply pipe are still in a closed state. The low-temperature secondary refrigerant prepared by the refrigerating unit enters the ice storage tank from the secondary refrigerant pipe 1 and flows into the ice storage coil 17 through the right secondary refrigerant header 14. The secondary refrigerant exchanges heat with the water outside the pipe in the ice storage coil 17, the temperature is raised to form high-temperature secondary refrigerant, the water outside the pipe is gradually frozen due to being cooled, and an ice layer is formed on the outer surface of the ice storage coil 17. The high-temperature secondary refrigerant flows out of the left secondary refrigerant header 13 through the ice storage coil 17 and flows back to the refrigerating unit through the secondary refrigerant outlet pipe 3.
And (3) an external ice melting process: the chilled water regulating valve I5 and the chilled water regulating valve II 19 are opened, the chilled water regulating valve II 6 and the chilled water regulating valve III 18 are closed, and the secondary refrigerant regulating valve III 7 and the secondary refrigerant regulating valve IV 8 which are positioned on the secondary refrigerant outlet pipe, the secondary refrigerant regulating valve I9 and the secondary refrigerant regulating valve II 10 which are positioned on the secondary refrigerant pipe 1 are all in a closed state. The high-temperature chilled water heated by the air conditioner user end enters the ice storage tank from the air conditioner water return pipe 2 and flows into the left water distribution pipe 15 through the left water distribution pipe header 11, a plurality of spray holes are formed in one side, facing the ice storage coil 17, of the left water distribution pipe 15, and the high-temperature chilled water is sprayed to the outer ice layer of the ice storage coil 17 through the spray holes. The high-temperature chilled water flows slowly on the ice layer outside the pipe along the length direction of the coil pipe, and the high-temperature chilled water and the ice layer exchange heat to form low-temperature chilled water. The low-temperature chilled water flows out of the ice storage tank from the air conditioner water supply pipe 4 and flows into the air conditioner user side through the air conditioner water supply pipe 4 to form a chilled water loop. When the left and right outflow directions of the high-temperature chilled water need to be switched, the chilled water regulating valve II 6 and the chilled water regulating valve III 18 are opened, the chilled water regulating valve I5 and the chilled water regulating valve IV 19 are closed, and the secondary refrigerant regulating valve III 7 and the secondary refrigerant regulating valve IV 8 which are positioned on the secondary refrigerant outflow pipe, the secondary refrigerant regulating valve I9 and the secondary refrigerant regulating valve II 10 which are positioned on the secondary refrigerant pipe 1 are in closed states. High-temperature chilled water heated by an air conditioner user end enters the ice storage tank from the air conditioner water return pipe 2 and flows into the right water distribution pipe 16 through the right water distribution pipe header 12, a plurality of spray holes are formed in the right water distribution pipe 16 on the side facing the ice storage coil 17, and the high-temperature chilled water is sprayed to the outer ice layer of the ice storage coil 17 through the spray holes. The high-temperature chilled water flows slowly on the ice layer outside the pipe along the length direction of the coil pipe, and the high-temperature chilled water and the ice layer exchange heat to form low-temperature chilled water. The low-temperature chilled water flows out of the ice storage tank from the air conditioner water supply pipe 4 and flows into the air conditioner user side through the air conditioner water supply pipe 4 to form a chilled water loop.
The flow direction switching time of the refrigerating medium in the icing process can be half of that in the icing process, and the refrigerating medium can also be repeatedly switched for many times in the icing process; the switching time of the flow direction of the frozen water in the ice melting process can be performed when the ice melting process is performed to half, and can also be repeatedly performed for a plurality of times in the ice melting process.
Finally, it is also noted that the above-mentioned list is only a few specific embodiments of the present invention. Obviously, the present invention is not limited to the above embodiments, and many modifications are possible. All modifications which can be derived or suggested by a person skilled in the art from the disclosure of the invention should be considered as within the scope of the invention.
Claims (3)
1. Improve the device of the icing ice-melt efficiency of coil pipe formula ice cold-storage, its characterized in that: comprises an ice storage tank;
an ice storage coil pipe (17), a left secondary refrigerant header (13), a right secondary refrigerant header (14), a left water distribution pipe header (11) and a right water distribution pipe header (12) are arranged in the ice storage tank;
the left secondary refrigerant header (13) and the right secondary refrigerant header (14) are respectively positioned at the left side and the right side of the ice storage coil pipe (17) and are communicated with the ice storage coil pipe; the left water distribution pipe header (11) is positioned on the left side of the left secondary refrigerant header (13), and the right water distribution pipe header (12) is positioned on the right side of the right secondary refrigerant header (14); the left water distribution pipe header (11) is connected with the left water distribution pipe (15);
the left secondary refrigerant header (13) is communicated with an outlet of the ice storage coil pipe (17), and the right secondary refrigerant header (14) is communicated with an inlet of the ice storage coil pipe (17);
the secondary refrigerant pipe (1) is positioned at the outer side of the ice storage tank, the secondary refrigerant pipe (1) is divided into two paths which extend into the ice storage tank from the outer side of the ice storage tank, one path is connected with the left secondary refrigerant header (13) through the primary secondary refrigerant regulating valve (9), the other path is connected with the right secondary refrigerant header (14) through the secondary refrigerant regulating valve (10),
the left secondary refrigerant header (13) is connected with the secondary refrigerant outlet pipe (3) through a secondary refrigerant regulating valve III (7), and the right secondary refrigerant header (14) is connected with the secondary refrigerant outlet pipe (3) through a secondary refrigerant regulating valve IV (8);
the air conditioner water return pipe (2) is positioned outside the ice storage tank, the air conditioner water return pipe (2) is divided into two paths, the two paths extend into the ice storage tank from the outside of the ice storage tank, one path is connected with the left water distribution pipe header (11) through the chilled water regulating valve I (5), and the other path is connected with the right water distribution pipe header (12) through the chilled water regulating valve II (6);
the air-conditioning water supply pipe (4) is respectively connected with the air-conditioning user side and the ice storage tank.
2. The device for improving the efficiency of the coil type ice storage, icing and thawing of ice according to claim 1, wherein:
the inlet of the air conditioner water supply pipe (4) is divided into two paths, one path is provided with a chilled water regulating valve III (18), and the chilled water regulating valve III extends into an ice storage groove right below the left side of the ice storage coil pipe (17) to be communicated; the other path is provided with a chilled water regulating valve IV (19) which extends into the ice storage tank right below the right side of the ice storage coil pipe (17) to be communicated.
3. The device for improving the efficiency of the coil type ice storage, icing and thawing of ice according to claim 2, wherein:
a plurality of spray holes are formed in one side, facing the ice storage coil pipe (17), of the left water distribution pipe (15); the right secondary refrigerant header (14) is connected with a right water distribution pipe (16), and a plurality of spray holes are formed in one side, facing the ice storage coil pipe (17), of the right water distribution pipe (16).
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