RU192350U1 - DRYER - Google Patents

Abstract

The utility model is intended for drying vegetable agricultural products, mainly berries, fruits, vegetables and mushrooms. The dryer comprises a heat-insulated chamber with a door, a centrifugal fan heating rotor, nozzles for suction and discharge of a drying agent, each nozzle of a drying agent being connected to a heat exchanger. As a heat exchanger, a plate heat exchanger is used with two heat exchange surfaces dividing it into three chambers, one of which is an air solar collector with a translucent coating and nozzles for entering and exiting the spent drying agent, the middle chamber has inlet and outlet nozzles and partitions, forming channels for the passage of heated atmospheric air, which then enters the heat-insulated chamber, and the third chamber also has nozzles for entry and Exit exhaust drying agent, each outlet chamber has a heat-insulated valve, regulating the supply of spent drying agent or a plate heat exchanger or to the atmosphere. The technical result of the utility model is to increase the heat recovery coefficient and use the energy of solar radiation to heat the drying agent in the initial period of operation of the dryer until it reaches operating temperature in a heat-insulated chamber. 2 ill.

Description

The utility model is intended for drying vegetable agricultural products, mainly berries, fruits, vegetables and mushrooms.

Known aerodynamic drying installation (Patent for invention RU 2019777, Russian Federation, F26B 3/02, F26B 9/06. Method of drying products and aerodynamic drying installation / V.A. Ananyev, A.L. Basukinsky, A.G. Shaposhnikov, V.M. Petrushin; publ. September 15, 1994.), which contains a thermally insulated chamber with doors, pipes for suction and discharge of a drying agent and a centrifugal fan rotor located inside the chamber.

The disadvantage of this installation is the high heat loss with the emitted drying agent.

The closest to the claimed solution is a dryer (Utility Model Patent RU 161162, Russian Federation, F26B9 / 06. Dryer / Kh.M. Isaev, A.I. Kupreeenko, II Kulipatova; publ. 04/10/2016, Bull. No. 10.), Containing a heat-insulated chamber with a door, a heating rotor of a centrifugal fan and nozzles for suction and discharge of a drying agent. A shell-and-tube heat exchanger is installed on each discharge pipe of the drying agent.

The disadvantage of this installation is the low heat recovery coefficient of the spent drying agent due to the small heat transfer surface area of the shell-and-tube heat exchanger and the short contact time of the spent and heated drying agent with the heat transfer surface, as well as the inability to use solar energy to heat the drying agent in the initial period of operation of the dryer until it reaches operating temperature in a thermally insulated chamber.

The technical result of the utility model is to increase the heat recovery coefficient of the spent drying agent by increasing the heat transfer surface area of the heat exchanger and the contact time of the heated drying agent with the heat transfer surface, as well as by using the energy of solar radiation to heat the drying agent in the initial period of operation of the dryer until it comes out on the working temperature in a thermally insulated chamber due to the use of an air solar collector Ora as part of a heat exchanger.

The technical result is achieved in that a dryer containing a heat-insulated chamber with a door, a centrifugal fan heating rotor, nozzles for suction and discharge of a drying agent, each nozzle of a drying agent discharge connected to a heat exchanger. As a heat exchanger, a plate heat exchanger is used with two heat exchange surfaces dividing it into three chambers, one of which is an air solar collector with a translucent coating and nozzles for entering and exiting the spent drying agent, the middle chamber has inlet and outlet nozzles and partitions, forming channels for the passage of heated atmospheric air, then entering the insulated chamber, and the third chamber also has nozzles for entry and Exit exhaust drying agent, each outlet chamber has a heat-insulated valve, regulating the supply of spent drying agent or a plate heat exchanger or to the atmosphere.

The presence of partitions along the path of the heated drying agent in the middle chamber of the heat exchanger between two heat transfer surfaces of a larger area provides an increase in the contact time of the spent and heated drying agent with the heat transfer surface and, accordingly, an increase in the heat recovery coefficient of the spent drying agent. The use of an air solar collector in the heat exchanger as one of its chambers provides the use of solar radiation energy to heat the drying agent in the initial period of operation of the dryer until it reaches operating temperature in a heat-insulated chamber.

In FIG. 1 shows a diagram of a dryer; FIG. 2 is a cross-sectional view of a plate heat exchanger.

The installation consists of a heat-insulated chamber 1 with a door 2 and nozzles for suction 3 and exhaust 4 of a drying agent, a heating rotor 5 of a centrifugal fan with a drive motor 6, a three-chamber plate heat exchanger 7 with two heat exchange surfaces 8, dividing it into three chambers, one of which represents an air solar collector 9 with a translucent coating 10 and nozzles for input 11 and output 12 of the spent drying agent, the middle chamber has an input 13 and output 14 nozzles and partitions 15, forming channels 16 for the passage of heated atmospheric air, then entering the insulated chamber 1, and the third chamber also has nozzles for entering 17 and the outlet 18 of the spent drying agent, while each outlet pipe 4 of the insulated chamber 1 has a shutter 19, regulating the flow spent drying agent either to the plate heat exchanger 7 or to the atmosphere.

The dryer operates as follows: the plant material is loaded into the insulated chamber 1 through the door 2. The shutters 19 are in a position that blocks the supply of the spent drying agent to the chambers of the plate heat exchanger 7. Atmospheric air through the inlet pipe 13 enters the middle chamber of the plate heat exchanger 7, where moving through channels 16, it is heated by heat exchange with the heat exchange surface of the solar collector 9 and through the outlet pipe 14 of the middle chamber and the inlet pipe 3 heat oizolirovannoy chamber 1 is supplied to the heating rotor 5 which provides heating and circulation of drying medium in a closed circuit heat insulated chamber 1. Contacting with a dried raw material, a drying agent is saturated with moisture removed, and through the outlet nozzles 4 is partially discharged into the atmosphere. In this case, the heating of atmospheric air in the plate heat exchanger 7 is carried out only due to the energy of solar radiation.

Upon reaching the temperature of the spent drying agent, the temperature of the heated drying agent coming from the plate heat exchanger 7, the flaps 19 are placed in a position that provides the supply of the spent drying agent through the inlet pipes 11 and 17 to the plate heat exchanger 7, where it additionally heats up the atmospheric air by transmitting heat through heat exchange surfaces 8. The spent drying agent is removed from the plate heat exchanger 7 through the outlet pipes 12 and 18. This ensures an increase in the coefficient of utilization of heat and the use of solar energy to heat the drying agent in the initial period of operation of the dryer until it reaches its operating temperature in a heat-insulated chamber.

Claims (1)

A dryer containing a heat-insulated chamber with a door, a centrifugal fan heating rotor, nozzles for suction and discharge of a drying agent, each exhaust pipe of a drying agent is connected to a heat exchanger, characterized in that a plate heat exchanger with two heat exchange surfaces sharing it is used as a heat exchanger into three chambers, one of which is an air solar collector with a translucent coating and nozzles for entering and exiting of the drying agent, the middle chamber has inlet and outlet nozzles and partitions forming channels for the passage of heated atmospheric air, then entering the insulated chamber, and the third chamber also has nozzles for entering and exiting the spent drying agent, with each outlet nozzle of the insulated chamber a damper regulating the supply of the spent drying agent either to the plate heat exchanger or to the atmosphere.

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