RU2001363C1 - Milk cooling device - Google Patents

Abstract

Usage: in agricultural production and food industry for cooling milk during processing and storage. Essence: the device contains a heat exchanger, sources of artificial and natural cooling, the last of which contains a cylindrical container located in the upper part of the atomizer, connected to the pipeline for the heated coolant, an additional U-shaped atomizer mounted on the outside of the walls of the container with rotation around her. On its vertical sections from the side of the tank, radial holes are made. Plates are installed in the tank, which are arranged stepwise one above the other with an inclination in the direction of movement of the coolant. The device is equipped with an external air flow stimulator for pumping it into the lower part of the tank cavity and moving it in countercurrent to the sprayed coolant. Under the tank there is a collection of cooled refrigerant in the Cahors vertical heat-insulated partitions, between the lower and upper edges of which and the base of the collector, slotted holes are made with the formation of a zigzag aznogo channel for transferring the coolant zlf 2-ly 1 and

Description

The invention relates to the cooling of liquid products, in particular milk, and can be used in agricultural production and the food industry for cooling milk during its processing and storage.

A device for cooling milk is known, comprising a heat exchanger, a water pump, a reservoir, a screen, partitions, control valves, a tray with a drain hole, a fan, a spray.

The closest in technical essence to the present invention is a device for cooling milk containing a thermally insulated tank, a heat exchanger, an internal atomizer with aerodynamic plates, an inclined pipe, an intermediate tank, a refrigerating machine, a control unit, a supply pipe, temperature sensors, a water pump, a screen controlled valves.

The disadvantages of these devices are low power dissipation and low cooling capacity.

The goal is to increase the cooling capacity of the device by increasing dispersion.

The goal is achieved in that in a device consisting of a thermally insulated tank with partitions, a heat exchanger, an internal atomizer with aerodynamic plates, an inclined pipe, an intermediate tank, a refrigerating machine, a control unit, a supply pipe, temperature sensors, a water pump, a screen controlled valves, a hollow cylinder with internal and external rotating nozzles located inside and outside it is installed, and the external atomizer is U-shaped.

An external nozzle is connected in the center through a hollow bearing device to the supply pipe. Such a connection allows the atomizer to rotate around the hollow cylinder while supplying recycled water through the supply pipe.

Radial holes are made along the generatrix of the vertical pipes of the external atomizer, perpendicular to the axis of the pipes in opposite directions, which causes it to rotate.

Inside the hollow cylinder, beneath the internal atomizer, sloping surfaces are mounted on top of each other so that there are slotted holes between the opposite ends of the surfaces and the inside of the hollow cylinder. Inclined surfaces increase the path of movement of water along the hollow cylinder.

At the bottom of the hollow cylinder there is a pallet, inside a thermally insulated

insulated partitions are installed in the tank, and the heat exchanger is made of flow type. A fan is installed in the lower part of the hollow cylinder, in the inclined surface space, which enhances the cooling effect of the circulating water, thereby increasing the cooling capacity of the installation, and there is a float regulator in the intermediate tank.

5 The drawing shows a General view of the device.

The device comprises a heat-insulated tank 1, a flow heat exchanger 2, an inclined pipe 3, an intermediate tank 4, a refrigerating machine 5. a control unit b, water temperature sensors 7, outdoor air 8, a water pump 9, a screen 10 located above the hollow cylinder 11, controlled valves 12 - 18,

5 mounted on the supply pipe 19, inside and outside the hollow cylinder 11 are located a rotating internal atomizer 20 with aerodynamic plates 21 and an external atomizer 22, the latter being more U-shaped and connected through the hollow bearing device 23 to the feeding pipe 19. the vertical pipes of the external sprayer 22 are made by radial spray holes 24 located perpendicular to the axis of the pipes in opposite directions, and inside the hollow cylinder 11 below the internal sprayer 20 on the other hand, inclined surfaces 25 are mounted on different sides so that there are slotted holes 26 between the opposite ends of the surfaces 25 and the inside of the hollow cylinder 11. In the lower part of the hollow

5 of cylinder 11, there is a drain pan 27, insulated partitions 28 are installed inside the thermally insulated tank 1. A fan 29 is installed in the lower part of the hollow cylinder 11 in the inclined surface space. A float regulator 30 is located in the intermediate tank 4.

The device is used to cool milk all year round.

5 Depending on the ambient temperature, the following operating modes are possible.

At an ambient temperature above 2 ° C, the device is used for accumulation and use of a type of artificial malt, and at temperatures below 2 ° C it is used in the accumulation mode and use of natural cold. The operating modes of the device are selected by the control unit 6 according to the indication of the air temperature sensor 8. installed outside the insulated room

In the accumulation mode of artificial cold, water from the intermediate tank 4 by the water pump 9 is supplied through controlled wengils 13 and 14 to the refrigeration machine 5, where it is cooled to the set temperature (below 2 ° C), then through the pipe 1 / through valve 18 into the extreme section of the heat-insulated tank 1. Water, displaced through the lower and upper sections of the heat-insulated partitions 28, enters the intermediate tank 4 through an inclined pipe and the cycle repeats. The thermal insulation of the partitions 28 makes it possible to maintain a constant water temperature at the outlet of the thermally insulated tank 1 for the duration of one cycle. Artificial cold accumulates in the spaces between milking.

In the mode of using the accumulated artificial cold, water from the intermediate tank 4 is supplied by the water pump 9 through the controlled valve 12 to the flow heat exchanger 2, where it removes heat from the milk, then through the controlled valves 15 and 18 it flows through the pipeline to the extreme section of the insulated tank 1. At the same time, part of the circulating water is supplied through the control valve 14 to the refrigeration machine 5, then these flows are connected in the pipeline system and through the controlled valve 10 enters the heat-insulated ervuar 1. In this case, the water temperature at the inlet insulated reeerou- ara 1 will be lower than the temperature of the circulating water flow at the outlet of the heat exchanger 2. This allows a 2 ... 3 times to reduce the installed power holo-

LARGE ME LINE.

In the mode of using the accumulated natural chill, the circulating hearth after the heat exchanger 2 is supplied through controlled valves 15.16.17, feed pipe 1 19 and hollow bearings; with () 3.:C1 va 23 to the external and internal circuits .; Shelley 22 and 20 External sprayer 22 is made in the form of a U-shaped and solen. i n dschtre through a hollow bearing / g state.if v 23 with a supply pipe 19, and on r |, v vertical pipes of the external rg l. pg-rt-, 22 radial sprayer., -,: .-. h 24 When a reverse i htt is supplied, the RF-absorber due to the reactive force of water, it is driven by a clockwise movement around the hollow cylinder 11. Sprayed water , releasing part of the heat it delivers to the outer surface of the hollow cylinder 11, where it transfers another part of the heat to the environment, then it is discharged through the lower tray 27 to the extreme section of the insulated tank 1. Some of the water enters the internal atomizer 20, where it is sprayed inside the hollow cylinder 11. To increase heat transfer inside the hollow cylinder ndra 11 installed inclined surface 25, which allow to increase the path of the water passage. Sprayed water, falling onto the upper inclined surface 25, is discharged through the slotted hole 26 between the inclined surface and the inside of the hollow cylinder 11 onto the second inclined surface, etc. Thus, water passes through all inclined surfaces 25 and enters through the lower drain pan 27 into the extreme section of the insulated tank 1. Aerodynamic plates 21 are installed on the internal spray 20, which, when the spray is rotated, take air from the lower openings of the hollow cylinder 11 and feed towards the sprayed water.

A fan 29 is installed in the lower inter-inclined surface space. A fan 29 supplies cold air from the environment to the inter-inter space, where it intensively cools the circulating water, which merges along the inclined surfaces 25, and simultaneously cools them. In this way, air is supplied through the inter-inclined surface spaces towards the sprayed water, then through the openings between the hollow cylinder 11 and the screen 10 into the environment. This increases the heat transfer from the sprayed water, and also increases the rotation speed of the internal spray 20. The screen 10 is mounted on top of the hollow cylinder 11 and prevents the ingress of external sediment into the insulated tank 1. The water level about the intermediate reservoir 4 is maintained by the float controller 30.

In the accumulation mode of natural cold, at the signal of the outdoor temperature sensor 8, water from the intermediate tank 4 by the water pump 9 is supplied through controlled valves 13, 15, 16 and 17 to the external and internal nozzles 22 and 20, where it is intensively cooled and flows to the extreme section of the warm bathtub Reserowar 1, then, PYTRGNCHR the rest of the warmed GENERATION through the lower and upper sections of the TR suite

bathroom partitions 28 and the inclined pipe 3 enters the intermediate tank 4. Next, the cycle is repeated. The temperature of the water in the insulated tank 1 during cooling of the milk and accumulation of artificial and natural cold is monitored by the water temperature sensor 9. To avoid freezing of water in the piping system located outside the premises, after the end of the modes

Claims (3)

1. MILK COOLING DEVICE, Containing a heat exchanger with pipelines connected to it for supplying cooled and discharging the heated coolant, sources of artificial and natural cold, the last of which contains a cylindrical container located in its upper part, an atomizer connected to the pipe for a heated coolant located under the tank of a collection of refrigerated coolant, an intermediate tank communicated by an inclined pipe with a collector and through a pump with a pipe for ode to the heat exchanger, control unit, characterized in that the source of natural cold is provided with an additional U-shaped atomizer connected in the central part of the horizontal section to the pipeline for the heated refrigerant carrier, the additional atomizer being installed on the outside of the vessel walls for storage and using the natural cold, a signal is sent from the control unit 6 to open the controlled valves 16, 17 and 18 while the water is being drained into the insulated tank 1. (56) Copyright certificate of the USSR N 1632124, cl. F 25 D 1/00, 1990. USSR copyright certificate No. 1531891, cl. A 01J 9/04, 1990. rotation around it, and on its vertical sections from the side of the tank radial holes are made, and in the tank there are plates arranged stepwise one above the other with an inclination in the direction of movement of the sprayed coolant and with the formation zigzag channel to move it. 2. The device according to claim 1, characterized in that it is provided with an inducer of the flow of external air, the discharge pipe of which is in communication with the cavity of the container in its lower part. 3. The device according to claim 1, characterized in that vertical heat-insulated partitions are installed in the chilled coolant collector, slotted openings are made between the upper and lower edges of the collector and the base of the collector to form a zigzag channel for moving the coolant.