SU552041A1 - Servo drive for a combine harvester engine cooling system - Google Patents

Description

one

The invention relates to the field of agricultural engineering and is aimed at improving the follow-up drive for the engine cooling system of a combine harvester, containing an air intake with a rotary valve in its cavity, periodically blocking the air inlet section through it to clean its filter section; They are light Vitajush, their particles of straw and chaff.

Drives for such a cooling system for a combine harvester engine, comprising a hydrocyliidre, the stem of which is connected to the rotary valve of the air intake housing, and the cavities connected to the output channel of the manually controlled distributor, are known.

The closest drive for the engine cooling system of a combine harvester closest to this technical solution provides automatic actuation of the valve when a certain degree of clogging of the filtering surfaces of the air intake is achieved. The actuator contains a hydraulic cylinder, the rod of which is connected to the rotary valve of the air intake housing, and its working cavity is connected to the output channel of the distributor.

In such a drive, a sensor is included in the valve control system, the sensitive element of which reacts to a change in pressure in the air intake cavity,

caused by a change in the flow area of the filter elements as a result of their clogging.

A disadvantage of the known follower drive is its complexity due to the choice of a membrane type sensor. The sensing element of such a sensor in the range of pressure difference in the air intake cavity creates a power pulse insufficient to switch the distributor and requires the introduction of an additional amplifier in the form of an electromagnetic switch.

The purpose of the invention is to simplify the construction of the servo drive of the engine cooling system of a combine harvester.

This is achieved by the fact that in it one of the walls of the inlet is made movable and kinematically connected to the inlet of the distributor, the movable wall of the inlet is connected to it pivotally with the possibility

angular displacement, and the kinematic connection of the movable wall of the air intake with the distributor is made in the form of a rotary valve, on which is mounted the hook of the rotary latch connected to the movable

wall. Making one of the walls of the air intake of the engine cooling system of a combine harvester movable and kinematically connected directly to the distributor allows it to be used as a pressure sensor. In this case, the provision in the range of pressure drop in the air intake cavity of the necessary power pulse of such a sensor for direct switching of the hydraulic cylinder distributor connected to the rotary valve is achieved by simple selection of the parameters of the moving wall. This eliminates the need to use in the follow-up drive not only special sensors, but also means that amplify their signals. FIG. 1 shows schematically a follower drive for an engine cooling system with an air intake, the bottom of which is rotatable and kinematically connected to the distributor of the hydraulic cylinder of the rotary valve (the rotary valve is in the open position); in fig. 2 - the same, but in the closed position of the rotary valve; in fig. 3 is a variant of the kinematic connection of the movable wall of the air intake in the open position of the rotary valve; in fig. 4 - also, in the closed position of the valve. The following drive for the engine cooling system of a combine harvester is a hydraulic cylinder I (Fig. 1) and a distributor 2. A single-acting hydraulic cylinder 1 is placed on the air intake housing 3, and its rod 4 is kinematically connected to a rotary valve 5 installed in the air intake cavity. The valve 2 spool type with axially movable spool contains input 6 and output 7 channels. The first one is connected to pressure source 9 by pipeline 8, and the second pipe 10 to the working cavity 11 of hydraulic cylinder I. Distributor spool 2 is kinematically connected to one of the walls of air intake housing 3. Air intake housing 12 is kinematically connected to the control valve spool and is relatively movable relative to the rest part of the body and is its pivoting bottom, attached to the body by its one edge using an axial hinge 13 and the other edges by means of a movable elastic seal 14. The kinematic linkage spool distributor 2 with the movable wall 12 of the inlet housing is designed as a rod 15 pivotally connected to both the spool and the movable wall. The following drive operates as follows. With a normally functioning cooling system, the air through the filtering surface 16 of the air intake 3 penetrates into its cavity and then through the window 7 by the fan 18 is sucked into the cavity of the radiator 19. The movable wall 12 - the bottom of the air intake housing 3 - under the influence of gravity and, acting on the distributor 2, holds its spool in a position connecting the cavity 11 of the hydraulic cylinder 1 with the discharge channel 20. In this case, the piston 21 of the specified hydraulic cylinder is held by the spring 22 in the upper edge This position and the rotary valve 5 connected with its stem 4 are in the open position. When, as the filtering surface 16 of the air intake 3 clogs, the pressure in its cavity drops to a predetermined limit, the swivel bottom retracts in the direction of the air intake cavity and takes up the position in accordance with FIG. 2. In this case, the rotary bottom, moving in a given direction, moves the spool of the distributor 2 to the position of pumping the working fluid into the working cavity 11 of the hydraulic cylinder I. Its piston 21 is set to the lower extreme position, which is escorted by moving the rotary valve 5 to the closed position windows 17. When the pressure in the inner cavity of the air intake is equalized with the external pressure, which is accompanied by cleaning the filtering surface 16 from small particles of chaff and straw settled on it, the rotary bottom under the force of gravity goes down and switches the distributor to the position of draining the working fluid from the cavity 11 of the hydroclipdra 1. At this, prulsina 22 moves the torpedo 2 to the uppermost polish, which is accompanied by retraction of the rotary valve 5 from the window 17. Subsequently the cycle repeats as it clogs filter 1, and its surfaces 16 of the air intake 3. As shown in FIG. 3, 4, the kinematic connection of the basement wall 23 with the distributor 24 to be performed and by means of the rotary valve 25 of the air intake 3. In this case, the connection of the movable wall and the valve is periodically disconnected in the form of a hook 26 and fixed the rotary latch 27 is connected to the movable wall, and the connection of the rotary valve with the rod 28 of the hydraulic cylinder 29 is through a sleeve 30 mounted on the rod with the possibility of axial movement. Such a kinematic connection of the basement: the wall with the distributor accelerates the process of shutting down the windows 17 of the radiator 19, which in turn entails a sharp increase in the pressure drop in the air intake cavity and, as a result, more intensive and high-quality discharge of dust mass from its filtering surface. Such a follower drive operates as follows. In the open field, the eip of the window 17 (Fig. 3) is a basement of the steak 23 and the valve 25 is retracted in

the lowest position and interconnected by the hook 26 and the latch 27. The working cavity 31 gpdrotsilpndra 29 is connected to the drain. In this case, the piston 32, under the action of the spring 33, is in its lowest position, and the sleeve 30 connected to the rotary valve 25 is retracted to the upper extreme position and holds the spring 34 in a compressed state. When clogged filtering surface

The 16 movable wall 23 rotates around the axis of the hinge 35 clockwise and opens the connection of the hook 26 with the latch 27. The released valve 25 under the influence of the spring 34 sharply closes the entrance window

Radiator 19 and at the same time switches the valve 24 to the discharge of the working fluid in the cavity hydrocyliidra 29 (Fig. 4). In this case, its rod 28 extends upward and, acting on the sleeve 30, returns the rotary valve 25 to its initial state. At the end of the return stroke of said valve, its hook 26 engages with the latch 27, with the result that valve 25 is held in the open position. At the same time, the valve 24 kinematically connected to the valve 25 switches to the position of draining the working fluid from the cylinder 29 cavity. Its piston 32 under the action of the spring 33 moves to the extreme lower position / hollow and compresses the spring 34 (Fig. 3).

The cycle then repeats as the filtering surface of the air intake clogs.

In both embodiments, the actuator uses a plunger hydraulic cylinder, however, it can be replaced with equal success.

cylinder double acting without changing the essence of the invention.

The proposed servo drive for the engine cooling system of a combine harvester, in which the function of the follower element, which reacts to the pressure drop in the air intake cavity and acts directly on the distributor of the actuating hydraulic cylinder, is performed by one

from the walls of the air intake case, mounted relatively to its movable, provides simplification and reliable automatic functioning without the use of special sensitive sensors and electromagnetic amplifiers.

Claims (3)

1. The next drive for the engine cooling system of a combine harvester, comprising a hydraulic cylinder, the rod of which is connected to the rotary valve of the air intake housing, and its working cavity is connected to the output channel of the distributor, which is different in order to simplify the design drive, one of the walls of the air intake is made movable and kinematically connected with the inlet of the distributor. 2. The actuator according to claim 1, characterized in that the movable wall of the air intake is connected to it pivotally with the possibility of angular displacement. 3. The actuator according to claim 1, characterized in that the kinematic coupling of the moving wall The air intake with the distributor is designed as a rotary valve, on which is mounted the hook of the rotary latch connected to the movable wall. .,. i J3 SP us ,. 25 17