SU547615A1 - Automatic evaporator defrost controller - Google Patents

Description

(54) AUTOMATIC CONTROLLER DEFROSTING EVAPORATOR

one

The invention relates to refrigeration equipment.

Automatic defrosting regulators are not known from the evaporator surface, consisting of an electric motor, a reduction gear combined with it, a cam mechanism, a switching device and a temperature sensor. Regulators ensure the inclusion of means of forced defrosting at certain time intervals and their disconnection upon expiration of a predetermined time interval or upon reaching the set value of the evaporator temperature 1.2.

An automatic evaporator defrosting regulator is also known, which contains a motor with a reducer, coupled with the latter and on one axis cams, a two-way switching mechanism and a temperature sensor 3.

The disadvantages of the known regulators include the difficulty of adjusting the duration of the defrosting process and large dimensions, due to the significant number of kinematic pairs of a reduction gearbox.

The purpose of the invention is to improve the accuracy of the controller and reduce its size.

This is achieved by the fact that the proposed regulator is equipped with a lever system with a protrusion connected with a transfer spring with a two-way switching mechanism, while the cams have depressions that serve to activate the defrost, and one of them has an adjustable protrusion to disable the defrosting.

FIG. 1 shows schematically the proposed controller, the view; in fig. 2 - the same, top view.

The automatic regulator of defrosting the evaporator of refrigeration units consists of an electric motor 1, on the axis of which the leading gear 2 is fixed. On axis 3, cams 4 and 5 are arranged in the form of disks of the same diameter with identical valleys 6 and 7. Gears 8 and 9, which are implemented at the same time as cams 4 and 5, respectively, have a different number of teeth and are fired with gear 2. On cam 4 is mounted adjustable protrusion 10.

A firing system 11 with a protrusion 12 with the help of a spring 13 is constantly pressed against the cams 4 and 5. By means of the reversing spring 14, the lever system 11 is connected to a two-position switching mechanism, namely, an elastic contact holder 15 having a contact 16. The switch is also provided with two fixed contacts 17 and 18. Thermal system 19 rests on the lower arm of the lever system 11.

The proposed automatic controller works as follows.

The rotation of the motor shaft 1 through gear 2 is transmitted to gears 8 and 9 and to cams 4 and 5, which are integral with them, since the gears have different number of teeth, for example MepZg 25 and Zg 24, the cams 4 and 5 rotate at different angular speeds. The defrost will occur when the protrusion 12 of the lever system 11 enters the depressions 6 and 7 of the cams 4 and 5. Thus, the defrosting process of the evaporator starts at intervals determined by the relative speed of rotation of the cams 4 and 5. The end of defrost will take place when the adjustable protrusion 10 on the cam 4 acts on the lever system 11. Consequently, the duration of the defrosting of the evaporator is determined by the speed of rotation of the cam 4.

The protrusion 12 of the drawing system 11 is constantly pressed by the spring 13 against the cams 4 and 5 and slides over their cylindrical surface. Lever system 11 through the spring 14 holds the contact holder 15 in the lower position. Contacts 16 and 17 controlling the operation of the chiller are closed. At each turn of cam 4, its adjustable protrusion 10 rotates the lever system 11 counterclockwise, without making the switching of contacts 16 and 17. When the protrusion 12 of the lever system 11 falls into the depressions 6 and 7 of the cams 4 and 5, the front system 11 rotates clockwise, The spring 14 passes the position of its unstable equilibrium and abruptly moves the contact holder 15 to the upper position. At the same time, contacts 16 and 17 are opened, and contacts 16 and 18 are closed, including the actuators of this cable.

Upon further rotation of the cams, the protrusion 12 of the lever system 11 emerges from cavities 6 and 7 onto the cylindrical surface of cams 4 and 5. The lever system then rotates counterclockwise, however, the spring 14 does not pass through the unstable equilibrium position and the contacts do not switch.

The adjustable protrusion 10, rotating with the cam 4, acts on the protrusion 12 of the lever system 11 and makes an additional turn counterclockwise, the spring 14 passes the position of unstable equilibrium and sharply moves the contact holder 15 to the lower position. In this case, contacts 16 and 18 are opened, and contacts 16 and 17 are closed. The defrost process is terminated.

The defrosting process can also be concluded with the help of the thermal system 19, which, upon reaching a certain surface temperature of the evaporator, acts on the riser system 11 and makes it turn counterclockwise. Spring 14 in this case also passes the position of its unstable equilibrium, opening contacts 16 and 18 and closing contacts 16 and 17.

Claims (3)

1.Patent of France No. 2024275, cl. F 25 D 21/00 from 1969 2. US patent number 3107281, cl. 200-38 from 1964 3. The patent of Germany No. 910306, cl. 17a, 4/01 of 1954 (prototype). 931 eight 6 L 1 ten FIG. 2