RU196646U1 - HYDRAULIC CLEANING MECHANIZED COMPLEX - Google Patents

Abstract

The hydraulic drive of a mechanized treatment complex is designed for use in underground mining when mining with an explosive atmosphere and can be used to supply hydraulic fluid in the form of an emulsion for hydraulic equipment of powered roof sections and oil to hydraulic actuators operating in cases where protection against ignition. It provides the use of oil to power the actuating hydraulic mechanisms in the presence of an explosive environment with thermal protection of the hydraulic system. There is a drift pump station with a working fluid in the form of an emulsion and with discharge and discharge hydraulic lines of the emulsion, which are located along the treatment mechanized complex. The pressure and discharge hydraulic lines of the emulsion have compensators for the successive movement of the sections of the powered roof support and the bends to the sections of the powered roof support for their hydraulic equipment. To actuate the hydraulic actuators with a working fluid in the form of oil, there is an oil station with a hydraulic motor. The pressure and drain hydraulic lines of the hydraulic motor are connected by taps to the section of the mechanized lining, respectively, from the pressure and drain hydraulic lines of the emulsion. The oil station has an oil pump driven by a hydraulic motor, an oil tank, a pressure and a suction hydraulic line of the oil pump. There is a fuse that can communicate the pressure line of the oil pump with the oil tank at a tripping temperature, the value of which is less than the flash point of the oil. 2 ill.

Description

The proposed utility model is intended for use in underground mining when mining with an explosive atmosphere and can be used to supply a working fluid in the form of an emulsion for hydraulic equipment of powered roof support sections and oil to hydraulic actuators operating in conditions of the need for protection against ignition .

Conducting treatment works requires the use of safe energy sources due to the difficult conditions of use in underground conditions. Under these conditions, the working fluid of hydraulic systems based on water, namely, water-oil emulsion, which is fed through extended hydraulic lines and whose use is safer than using oil, which is capable of igniting, especially at high temperature, has gained widespread use. However, the expansion of the functional capabilities of actuating hydraulic mechanisms is associated with the need to use oil as a working fluid, which, due to better lubricating properties and higher viscosity, provides more intensive operating modes.

A known hydraulic drive of a mechanized treatment complex, the design of which is taken as a prototype, comprising a drift pump station with a working fluid in the form of an emulsion and with discharge and discharge hydraulic lines of the emulsion, which are located along the mechanized treatment complex, have compensators for the successive movement of sections of the powered roof support and bends to the sections of mechanized lining for their hydraulic equipment. (Equipment for cleaning and tunneling: Catalog, Central Research Institute of Engineering and Coal, 1986, Fig. 24, p. 24-25). The disadvantage of this design is that the use of a water-in-oil emulsion for actuators having small dimensions and / or being intensively loaded (for example, a hammer, a winch or a hand tool) is inefficient due to its low viscosity and lubricity.

The objective of the proposed utility model is to ensure the use of oil to power hydraulic actuators in an explosive environment with thermal protection of the hydraulic system.

To achieve the specified technical result in the hydraulic drive of a mechanized treatment complex, which includes a drift pump station with a working fluid in the form of an emulsion and with pressure and drain emulsion hydraulic lines, which are located along the mechanized treatment complex, have compensators for the successive movement of the sections of the powered roof support and the bends to the sections of the powered roof for their hydraulic equipment, the following new features are applied.

To actuate the actuating hydraulic mechanisms with a working fluid in the form of oil, there is an oil station with a hydraulic motor, the pressure and drain hydraulic lines of which are connected by taps to the section of the mechanized roof support, respectively, from the pressure and drain hydraulic lines of the emulsion.

The oil station also has an oil pump driven by a hydraulic motor, an oil tank, pressure and suction oil pump lines.

There is a fuse that can communicate the pressure line of the oil pump with the oil tank at a tripping temperature, the value of which is less than the flash point of the oil.

The proposed utility model is illustrated by drawings, where in FIG. 1 shows a hydraulic diagram of a hydraulic drive of a treatment mechanized complex; in FIG. 2 is a hydraulic diagram of its oil station.

The hydraulic drive of the treatment mechanized complex contains a drift pump station 1 with a working fluid in the form of an emulsion and with a pressure 2 and drain 3 emulsion hydraulic lines, which are located along the treatment mechanized complex, have compensators 4 for sequentially moving sections 5 of the powered roof support and bends 6 to sections 5 of the powered roof for their hydraulic equipment 7. The drift pump station 1, as a rule, has an electric drive (not shown in the drawings). Compensators 4 of pressure head 2 and drain 3 of the emulsion hydraulic line are made in the form of a flexible sleeve, which is curved with a margin of length necessary for moving sections 4 of the powered support, and are located along the treatment mechanized complex.

For actuating hydraulic actuators, for example, a hammer, a winch or a hand tool (not shown in the drawings) with a working fluid in the form of oil, there is an oil station 8 with a hydraulic motor 9, the pressure 10 and drain 11 of which are connected by taps 6 to section 5 of the powered roof support , respectively, from pressure head 2 and drain 3 emulsion hydraulic lines.

The oil station 8 also has an oil pump 12 driven by a hydraulic motor 9, an oil tank 13, a pressure pump 14 and a suction 15 of the oil pump 12. The oil pump 8 is equipped with an open hydraulic system (Fig. 2), there is an oil drain 16 from the hydraulic actuator, and a suction The 15 hydraulic line of the oil pump 12 receives oil from the oil tank 13. In the case of an oil station 8 with a circulating hydraulic system, the suction 15 hydraulic line of the oil pump 12 receives oil from the hydraulic actuator.

There is a fuse 17 capable of communicating the pressure line 14 of the oil pump 12 with the oil tank 13 at a tripping temperature, the value of which is less than the flash point of the oil at which fire safety is ensured.

To increase the reliability and durability of the hydraulic system, a filter 18 can be applied installed in the drain 16 in the oil tank 13 hydraulic line. To prevent overloads and excessive pressure increase in the pressure line 14 of the hydraulic line of the oil pump 12, an overflow or safety valve 19 can be used, which can communicate the pressure line 14 of the hydraulic line of the oil pump 12 with a drain 16 in the oil tank 13 with a hydraulic line. To turn off and turn on the oil station 8, a hydraulic valve 20 can be used installed in the pressure head 10 of the hydraulic line of the hydraulic motor 9. To control the presence of pressure in the pressure line 14 of the hydraulic line of the oil pump 12, a pressure gauge 21 can be used, and a fuse 17 can be made with a trip indicator.

Maslostantion 8 may have an individual metal base (not shown in the drawing), with the help of which it is detachable or inseparably connected to that section 5 of the mechanized lining, the location on which it is convenient to use.

The pumping station operates as follows.

The drift pump station 1 feeds the emulsion along the pressure line 3 of the emulsion line and receives it back through the drain 3 line of the emulsion through taps 6 to the power support sections 5 for their hydraulic equipment 7. Compensators 4 allow you to move sections of the pressure 2 and drain 3 emulsion lines after the movable sections 5 of the mechanized hold on.

If necessary, use a hammer, a winch or a hand tool, using a crane 20 open the access of the emulsion to the hydraulic motor 9, which circulates through it through outlets 6 and puts it into action. The hydraulic motor 9 drives the oil pump 12, which delivers the oil through the pressure head 14 of the hydraulic line to the hydraulic actuators of the hammer, winch or hand tool.

If the hydraulic actuator of the hydraulic hammer, winch or hand tool does its work, then the oil through the drain 16 of the hydraulic line enters the oil tank 13 through the filter 18, from where it enters the oil pump 12 through the suction line 15. If there are interruptions in the operation of the hydraulic actuator without stopping the oil station 8, the oil through the overflow or safety valve 19 also enters the oil tank 13.

To stop the operation of the oil station 8, a crane 20 can be used, with which the pressure line 10 of the hydraulic motor 9 is closed, or the emulsion can be stopped to the hydraulic motor 9 in another way.

With heavy loads on the hydraulic actuator of the hydraulic hammer, winch or hand tool, with intensive use, or with prolonged inactivity, when the oil is pumped by the oil pump 12 through the overflow or safety valve 19 into the oil tank 13 for a sufficiently long time, due to the high resistance to oil movement in these In cases, an increase in oil temperature may occur. If the oil temperature reaches the temperature of the fuse 17, it trips and the oil exits the oil pump 12, along the path of least resistance, through the fuse 17, enters the oil tank 13, as a result of which the resistance to movement of the oil decreases and its heating decreases or stops . This reduces the pressure in the pressure line 14 of the hydraulic line of the oil pump 12, which is determined by the readings of the pressure gauge 21 and / or the alarm of the fuse 17, as well as the fact of the termination of the actuating hydraulic mechanism.

Then, with a crane 20, the pressure line 10 of the hydraulic motor 9 is closed or the supply of the water-based working fluid is stopped in another way and the reasons for the operation of the fuse 17, which are replaced or brought into operation, are clarified.

Thus, due to the fact that the operating temperature of the fuse 17 has a value lower than the flash point of the oil, which ensures the operation of the hydraulic actuator of the hydraulic hammer, winch or hand tool according to the fire safety condition, they solve the problem of thermal protection, which together with the supply of energy leading into the action of the pumping station, in the form of an emulsion flow, provides greater safety for the work of the oil station located near the executive mechanisms of mining machines 8 in explosive environments.

Claims (1)

The hydraulic drive of a mechanized treatment complex, comprising a drift pump station with a working fluid in the form of an emulsion and with discharge and discharge hydraulic lines of an emulsion, which are located along the mechanized treatment complex, have compensators for successively moving sections of a powered roof support and bends to sections of a powered roof support for their hydraulic equipment, characterized in that for actuating actuating hydraulic mechanisms with a working fluid in the form of oil, there is an oil station with a hydro a motor, the pressure and drain hydraulic lines of which are connected by branches to the section of the powered lining, respectively, from the pressure and drain hydraulic lines of the emulsion, the oil station also has an oil pump driven by a hydraulic motor, an oil tank, a pressure and suction hydraulic lines of the oil pump, and a fuse that can communicate with the pressure pump an oil tank at a response temperature whose value is less than the flash point of the oil.

Images