SU1245809A1 - Air drying unit - Google Patents

Description

The invention relates to the technique of ventilation and air conditioning and can be used, in particular, for drying air humidity.

The purpose of the invention is to increase the efficiency of air drying.

FIG. 1 is a schematic diagram of an air drying unit; in fig. 2 shows section A-A in FIG. one.

The air-drying unit comprises a rotor 1 with sorbents arranged in its flow-through cavity x 2, which can be made in the form of glasses 3 with the arrangement of the longitudinal axis of the glasses 3 parallel to the axis of rotation of the rotor 1.

The rotor 1 is placed in the housing 4, which has outlet nozzles 5 and 6, respectively, of dried air and air after regeneration with the possibility of periodically turning the rotor 1 inside the housing 4.

In the housing 4, a partition 7 is permanently installed, which is on one of the walls of the housing 4 and separates the housing 4 into two chambers 8 and 9. In the first chamber 8 of the housing 4 or on one side of the wall 7 there is a heater 10 and the dried air outlet 5 which through the partition (wall) 7 communicates with the second chamber 9.

In the second chamber 9 of the housing 4 (or on the other side of the wall 7) are located the outlet nozzle 6 of air after regeneration and the rotor 1, the latter being placed along the partition (wall) 7 with the axis of rotation perpendicular to the plane of the partition (wall) 7.

The rotor 1 is divided diametrically into four sector parts 11-14 (Fig. 2), in the flow section 2 of each of which glasses 3 with a sorbent are located.

The stepper drive 15 is kinematically connected with the rotor 1 and connected (not shown) to the humidity sensor 16 installed on the outlet nozzle 5 of the dried air. The supercharger 17 is connected to the inlet 18 of the dried air and outlet 19 through the flow cavity 2 with a sorbent to the outlet nozzle 5 of the dried air, as well as through the heater 10 and the flow cavity 2 with a sorbent to the air outlet 6 after regeneration.

Each of the four flow cavities 2 of the rotor 1 with glasses 3 with a sorbent has the ability to periodically communicate after turning the rotor 1 with the output

pipe 19 of the supercharger 17 and with the outlet pipe 5 of the drained air, as well as with the heater 10 communicated with the outlet pipe 19 of the supercharger 17 and with the outlet pipe 6 of the air after regeneration.

At the outlet of the outlet pipe 6 of the air after regeneration, a regulating locking element 20 can be installed. The air-drying installation works as follows.

By means of a blower 17 (for example, of a vortex type), the outside air is forced into the inside of the housing 1, further divided into two streams.

The dried air flow enters the flow cavity 2, where a glass 3 with a sorbent is installed, the passage through which the air is dried and then through the outlet 5 dried air is supplied to the consumer.

When the sorbent is gradually saturated with moisture in the flow cavity 2 of the rotor 1, the humidity sensor 16 of the stepper drive 15 automatically switches on, and the rotor rotates through an angle that ensures that the next flow cavity 2 of the rotor 1 is connected to work (if the rotor 1 is divided into four sectors parts It -14 - at 90 °).

Simultaneously with the dehumidification of the air, a part of the outside air supplied to the installation enters the heater 10 (for example, of the electric type), where the air is heated to the temperature required for the regeneration of the sorbent.

Further, the heated air is supplied (for example, countercurrent with respect to dried air) into the flow-through cavity 2 of the rotor 1, in which a sorbent is saturated with moisture, the sorbent is heated and the moisture is desorbed from it

whereby the humidified air is emitted into the atmosphere through the air outlet 6 after regeneration.

The regulation of the air flow rate for drying and regeneration can be carried out using the regulating locking element 20.

The implementation of the sorbent in the form of retrievable glasses ensures an even distribution of the air flow and facilitates the operation of the installation.

FIG. 2

Claims (2)

1. AIR DRYING INSTALLATION, comprising a housing with inlet and outlet nozzles, mounted in the housing with the possibility of periodic rotation around its axis, a rotor with four flow cavities, a sorbent placed in the flow cavities, a drained air blower connected to the inlet of the housing, one rotor flow cavity being connected to the inlet and one outlet nozzles of the housing, and the other flow cavity of the rotor with the inlet and other outlet nozzles, characterized in that, in order to increase the efficiency of air drainage, and equipped with a heater and a humidity sensor, the rotor has a step drive and is installed along one of the walls of the housing with an axis of rotation perpendicular to the plane of the wall, the sorbent is placed in all four flow cavities of the rotor, the step drive is electrically connected to a humidity sensor installed in one output pipe of the housing, the heater is located behind the inlet pipe of the housing before it is connected to one of the flow cavities of the rotor, and two of the four oppositely arranged are connected to the inlet and outlet pipes of the housing nnye its flow in the rotor cavity. 2. Installation according to π. 1, characterized in that the sorbent is made in the form of glasses installed parallel to the axis of rotation of the rotor in its flow cavities with the possibility of extraction. w QD O C © Fig 1