SU1268679A1 - Rack for testing valve units of bulldozer - Google Patents

Description

The invention relates to a testing technique and can be used for functional and life tests of switchgears for hydraulic systems of road-building machines, such as bulldozers.

The aim of the invention is to enhance the functionality and reduce the material intensity of the stand.

FIG. Figure 1 shows the hydraulic scheme of the test station for distribution devices, in which the distribution device is designed as a single-hammer, open-center distribution valve with a safety valve; in fig. 2 - the same, the distributor is made in the form of a one-hammer, n-type distribution valve with a closed center and a valve-controlled distribution valve of the safety-overflow valve; in fig. 3 - the same, the distributor is made in the form of a distributor with two three-position spools, one of which with an open center, and a safety valve; in fig. 4 - the same, the distributor is made in the form of a distributor with a three-position spool with an open center, two two-position switches and a safety valve; in fig. 5 - the same, the switchgear is made in the form of five two-position switches, and the unloading system of the additional pump - as a separate unit consisting of a switch and a safety valve; in fig. 6 - the same, the distribution device is made in the form of a valve-spool valve of a type distribution valve with remote electrohydraulic control, and the system of unloading an additional pump as a separate remote controlled relief overflow valve.

The stand (Fig. 1) consists of a main 1 and an additional 2 pumps connected by hydraulic lines 3 and 4 to distribution devices 5 and 6, the pump 2 supply being larger than the pump 1 supply. Devices 5 and 6 are connected to each other by hydraulic lines 7 and 8, in which a shut-off and regulating authority (ZRO) 9 is installed, and with tank 10, respectively, with hydraulic lines 11 and 12. In device 6, hydraulic lines 7 and 8 are connected by throttle 13 in the neutral position of the spool 14. Pumps 1 and 2 have discharge systems consisting of spools 14 and 15 and safety valves 16 (Fig. 1, 3 and 4) or These are safety valves 16, controlled by spools 14 and 15 (in Fig. 2) or remotely (Fig. 6), or consisting of a spool 15 and safety valve 16 and a separate switch 17 with a safety valve (Fig. 5).

The distribution device 6 consists of a spool 14 (Fig. 1 and 2) or of two spools 14 and 18 (Fig. 3), or of a spool 14 and two switches 19 and

20 (Fig. 4), or from five switches 21-25, installed respectively in hydrolines 26, 12, 27, 4 and 28 (Fig. 5), or from a spool 14, controlled by switches 29 and 30, and two valves 31 and 32 controlled by switches 33 and 34 (Fig. 6)

 Stand (Fig. 1) works as follows.

In the neutral position, the spools 15 and 14 of the devices 5 and 6 liquid from the main 1 and an additional 2 pumps hydraulically 3.4 and 11, 12 through the spools 15 and 14 merge into the tank 10. When the spool 14 of the device 6 is turned on in position A or and the neutral position of the spool 15 of the device 5, the liquid from the additional pump 2 through the hydroline 4 enters either through the hydrolysis of the research institute 8 or through the hydroline 7 to the ZRO 9 and the device 5, creating a pressure whose value is limited by the setting level of the valve 16. When the spool 14 is turned on the device 6 in position C or D gold By device 15, 5 is included, respectively, at position E and F.

When the spool 14 is turned on in the position C of the spool 15 to the position E, the liquid from the pump 2 enters the tank 4 through the device 6, ZRO

Q 9 and device 5, and from pump 1 along hydraulic lines 3, 8 and 12 - into tank 10 through device 5, ZRO 9 and device 6. The increased flow of the working fluid along hydraulic line 7 from device 6 to device 5, created by pump 2, includes ZRO 9 in working position, in which the hydrolines 7 are connected to the hydrolines 8 and the working fluid from the pump 2 is additionally drained through the device 6. The flow of the working fluid is exceeded than the nominal and simulated mode

0 "rapid lowering of the working body for the device 5 and ZRO 9.

When the spool 14 is switched from position C to position B (spool 15 remains in position), the hydroline 8 in the device 6 is uncoupled with the drain hydroline 12 and pressure is created in it by the pump 1, the value of which is limited by the setting level of the valve 16, which deactivates ZRO 9 and separation of the hydrolines 7 and 8. When the gold 14 is switched from position B to neutral position (spool 15 remains included in position E), fluid from pump 2 enters the drain through hydraulic lines 4 and 12 through spool 14, and from pump 1 nominal flow liquid STI enters tank 10 through hydro 5 m 3, 8, 7 and 11 through the spool 15 of device 5, ZRO 9 and choke 13 in device 6. In this case, choke 13 is used to create a load in device 5 and ZRO 9 and ZRO 9 from the mode “rapid lowering of the working body to the mode“ forced deepening of the working body.

When the spool 15 is turned on in the F position, the spool 14 is sequentially in the D and / 4 positions and the neutral position, the device 5 and ZRO 9 modes of operation are created similar to those indicated.

When the spool 15 is turned on at position C, spool 14 is turned on at positions C and D, while pump 1 is discharged through spool 15 of device 5, and increased fluid flow from pump 2 enters tank 10 through hydraulic lines 7 or 8, through hydraulic line 11 into tank 10 through ZRO 9 and device 5. A mode is created: the floating position of the working element of the device 5 and ZRO 9.

The stand (Fig. 2) works similarly to the stand (Fig. 1). The difference in operation is that unloading of pumps 1 and 2 in neutral positions of spools 15 and 14 is carried out only through valves 16.

The stand (Fig. 3) works similarly to the stand (Fig. 1). The difference in operation is that the positions L and S in the device 6 are created by simultaneously turning on the spool 14 in position N and spool 18 in position M or turning on the spool 14 in position L and spool 18 in position P, and positions C and) - turning on .m spool 14 to position L or N, spool 18 remains in the neutral position.

The stand (Fig. 4) works similarly to the stand (Fig. I). The difference in operation is that the positions b and L in the device 6 are created by simultaneously turning on the spool 14 to position L and switch 20 or turning on the spool 14 to position N and switch 19, and the positions C and D to turn on only spool 14 in position L and N respectively.

The stand (Fig. 5) works similarly to the stand (Fig. 1). The difference is that the pump 2 is unloaded through the switch 17, the positions L and S in the device 6 are created by simultaneously turning on the switches 17, 21 and 25 or 17,

21 and 24, and the positions D and C - by simultaneously turning on the switches 17, 21, 25 and 23 or 17, 21, 24 and 22.

The stand (Fig. 6) works similarly to the stand (Fig. 1). The difference is that the pumps I and 2 are unloaded by separate valves 16 with remote control, the positions L and S in the device 6 are created by turning on the spool 14 in position S or Г, and the positions C and Z) by turning on the spool 14 to position T and valve 32 or spool 14 to position 5 and valve 31.

Claims (5)

1. A test stand for testing a bulldozer switchgear, comprising a pump with a discharge system, a tank and a distributor connected to each other by hydrolines, and a shut-off and regulating unit, the input and output of which are communicated with the distributor, in order to extend the functionality and reduce material consumption, it is equipped with an additional pump with a discharge system, communicated with the inlet and outlet of the locking regulator by means of a four-line n-type switchgear, which The station is configured to communicate in one of its positions with a pump and a tank, and the inlet and outlet of the valve are each other through drossel. 2. A stand according to claim I, characterized in that the switchgear is made of two three-position distributors. 3. The stand according to claim 1, wherein the switchgear is made of a three-position distributor and two two-position switches. 4. A stand according to claim 1, characterized in that the switchgear is made of five two-position switches. 5. A stand according to claim 1, characterized in that the switchgear is made in the form of a valve-slide valve and a control valve with remote control. to 13 yy 12  5