RU2413142C1 - Source of cold - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention is designed for utilisation of cold of not traditional sources as melting ice or snow and can be used in systems of provision of premises with cold. The source of cold has a chamber for ice storage made in an upper part of a case. The bottom of the chamber is made as horizontal row of pipes of a contact heat exchanger parallel to each other and with a gap sufficient for drain of melt water. Horizontal rows of an intermediate heat exchanger are positioned under each pipe of the contact heat exchanger. A row of pipes forming an economiser are arranged lower. The economiser is equipped with a branch for supply of cooled liquid. The source of cold has a collector by means of which the branch of cooled liquid supply is connected with the branch of cooled liquid withdrawal via a system of pipes of the contact and intermediate heat exchangers. Lower parts of the pipes of the contact and intermediate heat exchangers are equipped with crowns. Upper surfaces of the pipes of the intermediate heat exchanger are furnished with drop catchers made as two symmetrical lengthwise profiled plates arranged with gap relative to surface of these pipes. The pipes of the intermediate heat exchanger have a drop-like shape with their round part upward. The pipes of the economisers are ribbed.

EFFECT: increased generation of cold due to raised regenerating capacity of cold source.

5 dwg

Description

The invention relates to the field of heat exchangers designed to produce low-potential liquid coolants, in particular for utilization of cold from unconventional sources in the form of melting ice or snow, and can be used in cold storage systems of premises.

A cold source is known, including a rectangular-shaped room buried in the ground, the walls of which are covered with heat and water insulation, and a pit of melting ice with a pipe for draining melt water is placed in the pit (Strashnov V.G. Rural residential building. - M.: Agropromizdat, 1989 g., Fig. 34).

The disadvantage of this design is the low cooling capacity and limited ability to restore the regenerative ability of a cold source.

Also known is a cold source, including a thermally insulated sealed enclosure with a thermally insulated sealed lid and a chamber for placing ice (see AS No. 1262221, IPC F25D 3/02, 1986).

A disadvantage of the known design is the low cooling capacity, low heat transfer coefficients from the melting mass and air to the cooled liquid, and also, due to the design features, a short inter-regeneration period.

The task to which the proposed technical solution is directed is to increase the cooling capacity by increasing the regenerative capacity of the cold source.

The technical result achieved in solving the problem is expressed in the intensification of heat transfer processes between melt water of the snow-ice massif and the cooled liquid, separated by heat transfer surfaces, which leads to an increase in cooling capacity.

The problem is solved in that the cold source, including a thermally insulated sealed enclosure with a thermally insulated sealed cover and an ice storage chamber, is characterized in that the chamber is made in the upper part of the cold source housing, while the bottom of the chamber is made in the form of a horizontal row of contact heat exchanger tubes parallel to each other to each other with a clearance sufficient for draining melt water, while horizontal rows of intermediate heat pipes are placed under each contact heat exchanger pipe exchanger, below which, in turn, is a series of pipes forming an economizer, while the economizer is equipped with a nozzle for supplying a cooled liquid, which through the inlet manifold is connected to the inlet openings of the economizer pipes, the outlet openings of which are connected to the outlet collector of the economizer connected to the inlet collector of the adjacent the overlying row of pipes of the intermediate heat exchanger associated with the output manifold of this series, while the output collector of each underlying row of pipes of the intermediate heat exchanger knitted with the inlet header of the overlying row of pipes of the intermediate heat exchanger, in addition, the outlet manifold of the uppermost row of pipes of the intermediate heat exchanger is connected to the inlet manifold of the pipes of the contact heat exchanger, the outlet manifold of which is equipped with a pipe for discharging cooled liquid, while the lower parts of the pipes of the contact and intermediate heat exchangers are provided with flanges moreover, the pipes of the contact and intermediate heat exchangers are installed so that their longitudinal axis and ridges belong to the same vertical In addition, the upper surfaces of the pipes of the intermediate heat exchanger are equipped with droplet eliminators made in the form of two symmetrical longitudinal profiled plates placed with a gap with respect to the surfaces of these pipes, in addition, the pipes of the intermediate heat exchanger are given a drop-shaped shape, facing the rounded part upwards, in addition , the economizer pipes are equipped with ribs, in addition, the lower part of the body cavity is equipped with a drain pipe equipped with a crane.

A comparative analysis of the essential features of the proposed technical solution with the essential features of analogues and prototype indicates its compliance with the criterion of "novelty."

Distinctive features of the claims solve the following functional tasks.

The sign "... the camera is made in the upper part of the body of the cold source ..." provides the movement of the coolant (melt water) from top to bottom under the action of gravity.

Signs "... the bottom of the chamber is made in the form of a horizontal row of tubes of a contact heat exchanger located parallel to each other with a gap sufficient for drainage of melt water, while below each tube of a contact heat exchanger horizontal rows of tubes of an intermediate heat exchanger are placed, below which, in turn, is a row pipes forming an economizer ... "allow you to consistently implement various types of heat removal, ensuring the maximum temperature difference of the cooling agent and the cooled liquid in pre affairs of each type of operation of the heat exchanger (the warmest cooled liquid interacts with the warmer coolant).

Signs "... the economizer is equipped with a coolant supply pipe, which is connected through the inlet manifold to the inlet openings of the economizer pipes, the outlet openings of which are connected to the outlet manifold of the economizer, connected to the inlet manifold of the adjacent overlying row of pipes of the intermediate heat exchanger, connected to the outlet manifold of this series, the output manifold of each underlying row of pipes of the intermediate heat exchanger is connected to the input manifold of the upper row of pipes of the intermediate heat exchanger In addition, the output manifold of the uppermost row of pipes of the intermediate heat exchanger is connected to the input manifold of the pipes of the contact heat exchanger, the output manifold of which is equipped with a nozzle for draining the cooled fluid ... ”allow all types of heat exchangers to be used sequentially (when pumping the coolant), thereby increasing the efficiency of the source cold.

The signs "... the lower parts of the pipes of the contact and intermediate collectors are provided with flanges, and the pipes of the contact and intermediate heat exchangers are installed so that their longitudinal axes and ridges belong to the same vertical plane ..." allow the sequential use of melt water formed at the ice contact with the contact heat exchanger in each of the rows of pipes of the intermediate heat exchanger (i.e., melt water does not immediately flow into the economizer’s “working zone”, but interacts sequentially with the pipes of each row yes intermediate heat exchanger.

The signs "... the upper surfaces of the pipes of the intermediate heat exchanger are equipped with drop eliminators made in the form of two symmetrical longitudinal profiled plates placed with a gap with respect to the surfaces of these pipes ..." are aimed at capturing the melt water dripping from the tubes of the overlying register and ensuring its film interaction (when spreading of captured drops) on the surface of the pipes of the corresponding row, which leads to intense heat transfer.

The signs “... the tubes of the intermediate heat exchanger are given a drop-shaped form, turned with the rounded part upwards ...” allow melt water in the film turbulent flow mode to wash the lower drop-like profile, providing additional heat removal.

The sign "... the economizer pipes are equipped with ribs ..." increases the intensity of the heat transfer process from the volume of melt water of the liquid pumped through the economizer.

The sign "... the lower part of the body cavity is equipped with a drain pipe equipped with a tap ..." eliminates the heating of the lower rows of pipes of the intermediate heat exchanger with melted water.

Figure 1 shows a cross section of a cold source; figure 2 is the same, a longitudinal section; figure 3 - node 1 of figure 1; figure 4 - node 2 of figure 1; figure 5 - node 3 of figure 2.

The cold source consists of a thermally insulated sealed enclosure 1 with a thermally insulated sealed cover 2 and a chamber 3 for placing ice. The heat-insulated hermetic casing 1 is made with double walls, the cavity 4 between which is evacuated with air pressure inside the cavity of 0.003 MPa. Sealed cover 2 is covered with thermal insulation on the outer walls. The chamber 3 is made in the upper part of the housing 1 of the cold source, while the bottom of the chamber 3 is made in the form of a horizontal row of pipes of the contact heat exchanger 5, arranged parallel to each other with a gap sufficient to drain melt water, while pipes of the intermediate heat exchanger are placed under each pipe of the contact heat exchanger 5 6, below which are placed the pipes of the economizer 7.

The contact heat exchanger 5 is made in the form of pipes 8 of large diameter, installed with a small horizontal gap, in the lower generators of which ridges 9 are installed, providing melt water in the form of droplets to the intermediate heat exchanger 6.

To ensure the drip-shock method of heat transfer of the intermediate heat exchanger 6, its horizontal pipes 10 are drop-shaped by welding to the lower semicircle of the profiled triangular channels 11 in communication with the cavity of the pipes 10 by means of longitudinal holes 12 in the lower forming pipes 10. On the lower generatrix of the droplet profile 11, flat distribution ridges 13 for organized and even distribution of flowing melt water to the underlying pipes. Above the upper semicircle of the tubes 10 is a droplet eliminator from the upstream tubes made of two symmetrical longitudinal profiled plates 14 fixed on the upper half of the tube profile 10 by spacer cylindrical pins 15. The droplet eliminator perceives the shock energy of the dropping drops, providing intensive heat transfer in the upper zone of the forming tubes 10 when spreading drops on the surface of the pipes. Further, the profiled plates 14 and the outer surface of the semicircle of the pipes 10 form slotted channels 16, in which a high speed of water movement is maintained due to the kinetic energy of the dropping drops, which causes intense heat transfer. Then melt water in the film turbulent mode of runoff washes the lower droplet profile 11, providing additional heat removal.

Each heat exchanger is equipped with horizontally located collectors 17 for uniform supply and removal of fluid.

The economizer 7 is equipped with a nozzle 19 for supplying a cooled liquid, which through the inlet manifold 17 is connected to the inlet openings of the pipes 18 of the economizer 7, the outlet openings of which are connected to the outlet manifolds 17 of the economizer 7 connected to the inlet manifold 17 of the adjacent overlying row of pipes 10 of the intermediate heat exchanger 6, connected with the output collector 17 of this series, while the output collector 17 of each underlying row of pipes of the intermediate heat exchanger 6 is connected to the input collector 17 of the overlying row of the intermediate heat oobmennika 6, moreover, the output collector 17 of the uppermost row of tubes 10 of the intermediate heat exchanger 6 is connected with an inlet manifold 17 of the heat exchanger pipes 8 contact 5, which is provided with an outlet header pipe 19 for withdrawing the cooled liquid.

Pipes 8 and 10 of contact 5 and intermediate 6 heat exchangers are installed so that their longitudinal axis and ridges 9 and 13 belong to one vertical plane.

The pipes 18 of the economizer 7 are placed inside the insulation on the outer walls of the lid along the cooled water, which have an external square fin.

In addition, the lower part of the cavity of the housing 1 is equipped with a drain pipe 19, equipped with a crane 20.

This design determines the tight fit of the melting massif to the heat exchange surface and the distribution of melt water to the lower step.

The ice mass is prepared in a cold source by gradually filling it with water during the winter period of the year and stored in it until the summer period. The compartment of the ice massif is made in the form of a truncated tetrahedral pyramid with an angle of the walls to the vertical of 1-2 degrees to prevent it from hanging during melting.

The cold source is installed in the open air under a canopy with an open lid 2, previously cooled water is drained from the water circuit through the drain pipe 19 by opening the tap 20. With a steady average daily negative outside air temperature, the slots in the base of the pipes 8 of the contact heat exchanger 5 are compacted with snow to prevent water leakage during ice generation by freezing. Then, filling the container by layer of water by spraying water in the ice compartment with the control of the freezing process of the monolithic ice massif takes place in layers. After completion of the freezing process in the cold season, the cold source is closed with an insulated lid 2 and the ice is stored in it with an internal temperature not exceeding 0 ° C until the warm season. In the warm season, the cooling water circulation is switched on, which ensures the process of ice melting.

Melt water enters the surface of the contact heat exchanger 5 and through the ridges 9 enters in the form of drops on the intermediate heat exchanger 6.

The droplet eliminator 11 perceives the shock energy of the falling droplets, providing intensive heat transfer in the upper zone of the forming tubes 10 when the droplets spread over the surface of the tubes. Further, through the slotted channels 16, in which a high speed of movement of water is maintained due to the kinetic energy of the dropping drops, which leads to intense heat transfer. Then melt water in the film turbulent mode of runoff washes the lower droplet profile 11, providing additional heat removal.

Claims (1)

A cold source, including a thermally insulated sealed housing with a thermally insulated sealed cover and an ice storage chamber, characterized in that the chamber is made in the upper part of the cold source housing, while the bottom of the chamber is made in the form of a horizontal row of contact heat exchanger tubes parallel to each other with a clearance sufficient for dripping of melt water, and under each pipe of the contact heat exchanger there are horizontal rows of pipes of the intermediate heat exchanger, below which, in turn, are a number of pipes forming an economizer is displaced, the economizer being equipped with a coolant supply pipe, which is connected through the inlet to the inlet openings of the economizer pipes, the outlet openings of which are connected to the output collector of the economizer, connected to the input collector of the adjacent overlying row of pipes of the intermediate heat exchanger, connected to the output collector this row, while the output collector of each underlying row of pipes of the intermediate heat exchanger is connected to the input collector of the overlying p poison of the pipes of the intermediate heat exchanger, and the output manifold of the uppermost row of pipes of the intermediate heat exchanger is connected to the input manifold of the pipes of the contact heat exchanger, the output collector of which is equipped with a branch pipe for cooling the liquid, while the lower parts of the pipes of the contact and intermediate heat exchangers are provided with flanges, and the pipes of the contact and intermediate heat exchangers are installed so that their longitudinal axes and ridges belong to the same vertical plane, while the upper surfaces of the pipes are intermediate of the heat exchanger are equipped with droplet eliminators made in the form of two symmetric longitudinal profiled plates placed with a gap with respect to the surfaces of these pipes, and the pipes of the intermediate heat exchanger are given a drop-shaped shape, facing the rounded part upwards, while the economizer pipes are equipped with fins, and the lower part of the body cavity is provided drain pipe equipped with a tap.

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