SU1561879A1 - Hydraulic combine system - Google Patents

Abstract

FIELD OF THE INVENTION The invention relates to agricultural machinery, in particular, to agricultural combines. The purpose of the invention is to increase the reliability of the combine, reducing operating costs and metal consumption. The proposed hydraulic system of an agricultural combine contains a hydraulic system for controlling technological equipment. The hydraulic system includes hydraulic motors, a pump of constant capacity, pressure and drain hydraulic lines, spool valves dispensed in parallel to pressure hydraulic lines on two control lines of hydraulic engines, for example, double-acting power hydraulic cylinders. Throttles and hydraulic locks are installed in the control lines of hydraulic engines. Hydrolocks have pusher plungers, on both sides of which face-mounted control chambers are located. Through an additional choke, a control channel is connected to the pressure line connected to the drain. The control channel has a side branch, also communicating with a drain through a constant pressure relief valve. One control line overflow valve is connected to the control channel before, and the other after additional throttle. The control channel is equipped with a shut-off device, made, for example, in the form of an electrically controlled shut-off valve, whose electrical control is connected to an electrically controlled distributor. The hydraulic system of the combine is characterized in that it is provided with an additional control channel, one end connected to the main control channel between the additional throttle and the locking device, and the plunger pushers of the hydraulic locks are made in the form of a spool with at least two. The other end of the additional control channel is connected to an inter-gate camera. The throttles in the control lines of the hydraulic engines are located in front of the hydraulic locks. 1 hp f-ly, 3 ill.

Description

FIELD OF THE INVENTION The invention relates to agricultural machinery, in particular to combines for harvesting agricultural crops.

The purpose of the invention is to increase reliability and reduce operating costs and metal consumption.

FIG. Figure 1 shows a schematic diagram of the system (for simplicity, the technological equipment of an agricultural combine is shown in part); in fig. 2 - a variant of the plunger-pusher design of the hydraulic lock; FIG. 3 is a view A of FIG. 2

The agricultural combine contains the process equipment, which includes the header 1 with the reel 2, the threshing drum 3, the unloading auger 4 and other working bodies not conventionally shown in FIG. 1. Process equipment is controlled by a hydraulic motor, for example, power cylinders. The threshing drum 3 is controlled by a hydraulic cylinder 5, and the unloading auger is controlled by a hydraulic cylinder 6. All consumers of hydraulic energy are included in a single hydraulic system, including pump 7, pressure hydraulic line 8, drain hydraulic line 9 and parallel distributors connected to pressure hydraulic line, in particular valve 10 and 11, performed on two control lines 12, 13 and 14, 15, respectively. Distributors may differ in both design and control. Thus, the distributor 10 has a manual control 16, and the distributor 11 - electric 17.

In lines 12, 13 and 14, 15 of the control of hydraulic cylinders 5 and 6, hydraulic locks 18 and 19 of two-way operation are installed with check valves 20, 21 and 22, 23 with pushrod pistons 25 and 26 placed between them in the body 24. pushers are made of control chambers 27, 28 and 29, 30, to which lines 12, 13 and 14, 15 of hydraulic cylinders 5 and 6 are connected. Hydrolocks can have an identical design. Fig 1 hydraulic lock 18 is shown in the schematic image, and the hydraulic lock 19 - in semi-constructive. In front of the hydraulic locks 18 and 19, throttles 31, 32 and 33, 34 are installed in the control lines of the hydraulic engines.

The hydraulic system has a main control channel 35, at one end connected to the drain hydraulic line 9, and the other connected to pressure hydraulic line 8 via an additional throttle 36. The control channel 35 has a lateral branch 37 connected to the drain hydraulic line 9 through a relief valve 38 having lines 39 and 40 control, of which the first is connected to the control channel 35 before the throttle 36, and the other after the throttle. The control channel 35 has a shut-off device, made, for example, in the form of a shut-off valve 41 connected to the valve of the distributor 11 by means of electrical communication. FIG. 1, the electrical connection of the electromagnet 42 controlling the shut-off valve 41 to the electric control 17 of the distributor 11 is conventionally not shown. But if you use the electric control 17 and transfer the valve of the distributor 11 to one of the working positions, the electromagnet 42 will automatically activate and the valve 41 will shut off the flow of fluid through the control channel 35 to the drainage line 9.

The locking device can be integrated with the valve of the distributor, as is the case with the valve 10. In this case, the valve itself

The valve is a shut-off valve. For this purpose, it contains an additional channel 43, which communicates the control channel 35 with a drain in the idle mode of the hydraulic system and in the neutral position of the distributor tray (as shown in the diagram). When the slide is shifted to one of the working positions, the channel 43 simultaneously moves, blocking the access of fluid through the control channel to the drain.

The hydraulic system is equipped with an additional

control channel 44. At one end, it is connected to the main control channel 35 in a space between the throttle and the locking device, for example, the locking valve 41. The other end of the additional

The control channel 44 is connected to the bore 45, which is made in the housing 24 of the plunger-pusher 26. At the same time, the plunger-pusher 26 is designed as a spool, has at least two speeds 46 and 47, and inter-spool chamber 48 between them. It is placed opposite the groove 45, so that the additional control channel 44 is connected to the inter-compartment chamber 48. Due to the small stroke of the plunger-pusher 26, skies 46 and 47 are forced close to each other. In order to prevent distortion of the plunger of the push rod 26, it is advisable to provide the latter with two additional trains 49 and 50 located on both sides of the main trains 46 and 47. Interposer chambers 51 and 52 between the main and additional routes communicate with the end control cameras and pusher plungers to enable the transmission of a pressure signal in the working cavity of the hydraulic motor via an additional control channel 44. One possible

The 0 message options of the said chambers are the design of spool 26 with flats 53 on additional sections 49 and 50. The throttles 31, 32 and 33, 34 installed in the control lines of the hydraulic motors are flow sensors. Wherein

5, the signal characterizing the flow rate is removed in the form of a pressure differential at these throttles and is supplied via an additional control channel and pressure hydroline to the overflow valve 38, ensuring constant pressure drop and, therefore, stabilizing the flow rate of the working fluid. The hydraulic system is provided with a safety valve 54 that prevents the system from overpressurizing above the set limit.

5 The hydraulic system of the combine works as follows.

The operator turns on the drive of the pump 7 of constant capacity. If the technological equipment of the combine is inactive

and the valves 10, 11 and others not shown in the diagram are in the neutral position, the working fluid flows through the main control channel with a small flow through the throttle 36 to the hydraulic line 9. At the throttle a pressure differential occurs through the lines 39 and 40 control to a normally closed (by spring action) overflow valve 38. Valve 38 opens, and the main part of the pump 7 supply is by-passed through side branch 37 to the drain. If it is necessary to put into operation any working body of the process equipment, for example, the unloading screw 4, the operator switches on the electrical control 17 of the corresponding distributor 11. Simultaneously with the movement of the spool of this distributor, one of the operating positions is automatically switched by electric connection (not shown) electromagnet 42 of the shut-off valve 41. The shut-off valve 41 will shut off the main control channel 35 and the flow of the working fluid through it will stop. The pressure drop at throttle 36 will become zero and the overflow valve will close under its spring, the working fluid overflow compartment will be drained through the side branch 37. In this case, the entire flow of working fluid pumped by pump 7 will flow through one distributor 11 14 or 15 of the hydraulic cylinder 6, depending on which position the distributor valve is in.

For the sake of definiteness, we assume that the top position of the spool is set, when looking at the circuit in FIG. 1. Then, the working fluid under pressure enters the line 14, into the end chamber 29 of the control of the hydraulic lock and then, pressing the check valve 22, into the rod cavity of the hydraulic cylinder 6. At the same time, the unloading screw 4 will be lowered. At the same time the fluid under pressure acts on the left end of the plunger-pusher 26, pushing it to the right. The right end of the plunger 26 opens the check valve 23, passing the fluid from the piston cavity of the hydraulic cylinder 6 to line 15 and then through the distributor 11 to the drainage line 9. When the plunger-pusher 26 is pushed to the right, the control chamber 29 communicates with the additional control channel 44 directly if the spool juicy {as shown in FIG. 1), or through the intergate chamber 51 and the gap formed between the flats 53 on the additional 48 and the body 24 of the hydraulic lock. Since, through the control chamber 29, the control passage 44 communicates with the rod cavity of the hydraulic cylinder 6, which in this case perceives the load on the working member, the fluid pressure in this passage is a signal that reflects the current

Q 5 5 0

5 0 5 5

load. Through the main control channel 35, to which the additional control channel 44 is connected, the signal controlling the load on the working element is fed through line 40 to the overflow valve 38. In addition, the valve 38 is affected by fluid pressure in the pressure hydraulic line 8. Since it characterizes the load on the working body pressure is the pressure after the throttles 33, and the pressure in the pressure line is the pressure in front of the throttle, then the valve 38 perceives the differential of these pressures, keeping it constant regardless of the load value and on the working body.

The magnitude of the pressure drop maintained by a constant is determined by the spring setting. Thus, the throttle 33 in this case performs the role of a flow sensor of the working fluid supplied to the hydraulic motor 6, which determines its necessary speed. While maintaining the pressure constant at the throttle, which serves as the flow sensor, the flow is automatically kept constant at the constant throttle cross section. When changing the working position of the spool valve 11, i.e. installing the bottom, if you look at the diagram in FIG. 1, position, the role of the flow sensor will take on itself choke 34.

In the case of the activation of a hydraulic motor controlled by the valve SO, having an "open center" with respect to the main control channel, the latter is blocked by shifting channel 43 relative to the control channel when translating the spool to one of the working positions. Thus, the spool of such a distributor performs the functions of a locking device similar to the shut-off valve 41. Otherwise, the operation of the hydraulic system is similar to that described.

When a low-loaded hydraulic engine is operating, the pressure in the system exceeds the pressure caused by the load by the value of the pressure differential across the throttle acting as a flow sensor. This pressure drop is relatively small and is determined from the condition of ensuring sufficient performance of the overflow valve 38. Thus, in the case of a low-speed, low-load consumer, the pressure in the pressure line is lower than the limit to which the safety valve is set. The unused portion of the pump feed is bypassed to a drain through an overflow valve 38 with a constant pressure drop, not through a safety valve, and with a smaller pressure drop, which increases the efficiency of the hydraulic system.

Claims (2)

1. The hydraulic system of the combine, which includes the hydraulic engines of the process equipment and the hydraulic system for controlling hydraulic engines, has a hydraulic pump, pressure and drain hydraulic lines, spool flow distributors installed on the control line of hydraulic engines parallel to the pressure hydraulic lines, chokes and hydraulic locks. ram pushers with end control chambers, a control channel connected to the drain, connected to the pressure hydroline through an additional throttle with an overflow valve and having a locking device, characterized in that, in order to increase reliability, reduce operating costs and metal consumption, the hydraulic system the combine is equipped with an additional control channel, one end connected to the main control channel between the additional throttle and the locking device, and each plunger-pusher of the hydraulic locks is made in the form of a spool with at least two ways forming the interstitial chamber, and the other end of the additional control channel is connected to the interstitial chamber, while the throttles in the control lines of the hydraulic engines are located in front of the hydraulic locks. 2. The combine system according to claim 1, characterized in that the hydraulic lock spools have additional features placed on both sides of the main axes, and inter-lateral chambers between the main and additional axes are in communication with the end chambers of the spools. 53 2t W 26 f6 Sad / I Fi.g.3