RU2682775C1 - Valve cluster - Google Patents

Abstract

FIELD: hydraulic engineering.SUBSTANCE: valve cluster comprises a control valve and a safety valve, wherein the safety valve inlet being connected to the control valve outlet, and the safety valve outlet being connected to a drain. Control valve and safety valve are installed on the same platform, in the volume of which a shaped channel is made, containing coaxial end sections provided with fittings and a channel parallel thereto, connected by the first and second branches lying in the same plane with the shaped channel, wherein the branches are continued by the first and second channels, made before reaching the platform surface, wherein between the first and second channels there is a third channel, connecting the platform surface and the shaped channel cavity, in addition, the first channel is configured with the possibility of fixing an electromagnetic valve as a regulating valve, made with the possibility of overlapping the first branch, whereas the second channel is made with the possibility of fixing a safety valve, made with the possibility of overlapping the second branch, and the third channel is made with the possibility of fixing a plug or fitting of a high-pressure hose of the accumulator, in addition, a hydraulic fluid temperature sensor configured to supply a control signal to the electromagnetic valve is installed in the hydraulic tank of the hydraulic system.EFFECT: invention simplifies the design and provides the possibility of reliable operation of the hydraulic system of equipment operated at low temperatures.3 cl, 2 dwg

Description

The invention relates to the field of engineering hydraulics and is intended to control the flow of fluid in volumetric hydraulic drives, especially in operating conditions at low temperatures.

Known brake valve, locking and regulating flow, which is a valve block of two types - control and safety valves. Information on this valve can be found in the catalog of the company Mannesmann Rexroth No. 27 551 / 03.92 and on the website http://www/boschrexroth.com/busines_units/brm/subwebsites/brm_catalogen/ Mobile_Controls / Mobile_Valves / xM_brm_61444.jsp. The brake valve locking and regulating a stream like FD of a series 2X.

The disadvantage is its complexity, due to the complexity of installing and sealing the check valve seats: the unloading valve seat is installed at the bottom (inside) of the main check valve, and the implementation of accurate blind surfaces presents considerable technological difficulty. This problem is very significant, taking into account the fact that the accuracy of regulation is determined primarily by the quality of the surfaces of both check valves.

A valve block is also known that contains a control valve and a safety valve, while the inlet of the safety valve is connected to the outlet of the control valve, and the outlet of the safety valve is connected to a drain (see RU No. 2312266 F16K 17/04, 2007).

The disadvantage is its structural complexity and the inability to ensure reliable operation of the hydraulic actuator in the conditions of its operation at low temperatures.

The problem solved by the invention, the simplification of the design, as well as enabling reliable operation of the hydraulic system of equipment operated at low temperatures.

The technical result that is manifested in solving the stated problem is expressed in ensuring a smooth turning on of the hydraulic system as it warms up, which eliminates sudden changes in pressure and temperature of the working fluid and, accordingly, reduces the wear of its components and the cost of spare parts.

To solve this problem, a valve block containing a control valve and a safety valve, while the safety valve inlet is connected to the outlet of the control valve, and the safety valve outlet is connected to the drain, characterized in that the control and safety valves are installed on the same platform, in the volume of which a figured channel is made, containing, equipped with fittings, coaxial end sections and a channel parallel to them, connected by the first and second branches, lying in one plane with a figured channel, the taps are continued by the first and second channels made before reaching the platform surface, moreover, a third channel is made between the first and second channels, communicating the platform surface and the cavity of the figured channel, in addition, the first channel is made with the possibility of fixation in it, as a control, electromagnetic valve, configured to overlap the first outlet, while the second channel is configured to fix in it a safety valve, configured to overlap of the second outlet and the third duct is adapted to fix therein plugs or high-pressure hose fitting accumulator, in addition, the hydraulic reservoir mounted hydraulic hydraulic fluid temperature sensor adapted to supply a control signal to the solenoid valve. In addition, the sections of the figured channel and the surface of the platform are parallel. In addition, nitrogen was used as the working agent of the energy accumulator.

A comparative analysis of the features of the claimed solution with the signs of the prototype and analogues indicates the conformity of the claimed solution to the criterion of "novelty."

The combination of features of the claims provides a simplification of the design, and provides the possibility of reliable operation of the hydraulic system of equipment operated at low temperatures. In this case, the features of the characterizing part of the claims solve the following functional tasks.

The signs “control and safety valves are installed on the same platform” provide the opportunity to simplify the design and minimize its dimensions.

Signs indicating that in the platform volume “a figured channel is made, containing, equipped with fittings, coaxial end sections and a parallel channel connected by the first and second branches lying in the same plane as the figured channel” provide switching safety and control valves, with the possibility of connecting an energy accumulator . At the same time, the availability of fittings, coaxial end sections provide switching of the valve block with the hydraulic tank of the hydraulic system.

Signs indicating that "the bends are continued by the first and second channels, made before reaching the platform surface", provide the ability to connect the safety and control valves to the figured channel of the platform.

Signs indicating that “between the first and second channels a third channel is made, communicating the surface of the platform and the cavity of the figured channel, provide the ability to connect the energy accumulator to the figured channel of the platform.

Signs indicating that "in addition, the first channel is made with the possibility of fixing in it, as a control, electromagnetic valve, configured to overlap the first outlet" provide the connection of the control valve to the input section of the figured channel of the platform.

Signs indicating that "the second channel is made with the possibility of fixing a safety valve in it, made with the possibility of overlapping the second outlet" provide the connection of the safety valve to the output section of the figured channel of the platform.

Signs indicating that "the third channel is made with the possibility of fixing plugs or fittings of the high pressure sleeve of the energy accumulator" provide the ability to connect the energy accumulator.

Signs indicating that "a hydraulic fluid temperature sensor is installed in the hydraulic tank of the hydraulic system, configured to supply a control signal to the electromagnetic valve" allows you to dump part of the hydraulic fluid from the hydraulic system until it warms up so that its viscosity drops to normal operating parameters .

Signs indicating that “the sections of the figured channel and the surface of the platform are parallel” simplify the organization of adjacencies to the platform at the optimal angle, control and safety valves, as well as plugs or fittings for the high-pressure sleeve of the energy accumulator.

Signs indicating that “nitrogen is used as the working agent of the energy accumulator” increase the safety of the energy accumulator, since they eliminate the risk of fire of hydraulic fluid in emergency contact with the working agent of the energy accumulator.

The invention is illustrated by drawings, where in FIG. 1 is a schematic sectional view of a platform; in FIG. 2 shows a schematic diagram of a device.

The drawings show a control valve 1, a safety valve 2, a platform 3, a figured channel containing coaxial end sections 4 and a parallel channel 5 connected by the first 6 and second 7 taps, the first 8, second 9 and third 10 channels, end fittings 11, high-pressure hose fitting 12, energy accumulator 13, hydraulic tank 14 of the hydraulic system, hydraulic fluid temperature sensor 15, control relay 16 of the electromagnetic valve (control valve 1), pressure channel 17 of the hydraulic system, non-return valve 18.

The valve block contains a control (electromagnetic) valve 1 and a safety valve 2, while the inlet of the safety valve 2 is connected to the outlet of the control valve, and the output of the safety valve 2 is connected to a drain connected to the hydraulic tank 14 of the hydraulic system. Regulating 1 and safety 2 valves are installed on one platform 3, in the volume of which a figured channel is made, containing, equipped with end fittings 11, coaxial end sections 4 and a channel 5 parallel to them, connected by the first 6 and second 7 branches, lying in the same plane with the figured channel. Taps 6 and 7 are continued, respectively, by the first 8 and second 9 channels, made before reaching the surface of the platform 3, while the sections of the figured channel and the surface of the platform 3 are parallel.

Between the first 8 and second 9 channels, a third channel 10 is made, which communicates the surface of the platform and the cavity of the figured channel (in the section of the parallel channel 5).

The first channel 8 is made with the possibility of fixing in it, as a control valve 1, an electromagnetic valve configured to overlap the first outlet 6, while the second channel is made with the possibility of fixing in it a safety valve 2, made with the possibility of overlapping the second outlet 7.

The third channel 10 is configured to fix plugs or fittings of the high pressure sleeve 12 of the energy accumulator 13 (nitrogen was used as its working agent).

The combination of valves 1 and 2 in one monoblock can significantly reduce the geometric dimensions of the structure and simplify the installation of the system. Also, in a monoblock, you can drill additional channels to connect additional equipment (for example, for the convenience of measuring hydraulic flow) and to improve the design. If necessary, unused openings can be closed with plugs.

In the hydraulic tank 14 of the hydraulic system is installed a temperature sensor of the hydraulic fluid 15, configured to supply a control signal to the electromagnetic valve (control valve 1).

The design is based on the following considerations. The operation of mining equipment includes a number of tasks related to the smooth operation of all machine components to fulfill production needs. In the Far North, cars are exposed to an aggressive environment where low temperatures prevail. The result of operation in such conditions is the failure of components and assemblies in the coldest period of the year.

An equally important aspect of the failure of the hydraulic system is unqualified operation. Often, equipment is put into operation without proper heating of the systems (especially for drilling rigs).

In addition to the unqualified operation of the equipment, its design failures are affected by design features (the equipment is equipped with new electronic control systems, which reduces the cost of manufacturing spare parts, overall dimensions, reduces the total weight of the machine), this leads to the use of electromagnetic valves, control pressures and a reduction in diameters channels, which, in turn, creates a problem of bandwidth and resource details.

So, it was revealed that, depending on the operating conditions, the elements of the hydraulic system fail in a different order. At temperatures below -30 ° C, high-pressure hoses and hydraulic cylinder and motor seals most often fail. During continuous operation at temperatures between -30 ° C and -20 ° C, hydraulic pumps are most often damaged. Also, in this temperature range, a cavitation effect on hydraulic valves was found, which sharply reduces their service life.

The reason for the failure of high pressure hoses, seals of hydraulic cylinders and motors is the difference in the density of the hydraulic fluid. The fact is that when the system starts, a new portion of the liquid from the axial piston pump entering the cavity of the actuating elements displaces the previous one, which has a slightly lower temperature and, as a result, a denser structure. This cold portion does not have time to leave the cavity of the actuator through an opening with a certain diameter leading to the drain line into the hydraulic tank. As a result, pressure is increasing in the system. A dense, cold fluid flow warms up when it enters the axial piston pump and internal compressive resistance. But it takes time to reach the operating temperature. During this time, the actuators are subjected to excessive loads. Their weak link is seals and high pressure hoses.

With a sharp increase in pressure (for example, with unskilled work of the operator, emergency or ensuring the safety of personnel moving executive bodies), the resource is reduced even faster, or leads to instant failure.

The reason for the failure of hydraulic pumps is the constant impact of heavy loads, which causes uneven heating of the structure. When compressing a dense flow, the plunger cavity is heated, locally heating the liquid covering the plunger walls. This thin layer, when overheated, loses its lubricating properties and leads to wear. Also, the heated and expanded plunger is located in the cold pump casing, which reduces the clearance of the mating precision pairs and also reduces the resource. In some cases, rapid heating of the fluid (especially when operating hydraulic oil with a viscosity of ISO VG 46 and higher) in a cold pump will cause it to stick.

The cavitation effect on hydraulic valves is caused by the flow of hydraulic fluid through the tapering hole of the valve. Excessively increased oil pressure as it passes through the sharp edges of the valve bore causes gas bubbles to form and collapse on the surface. This effect reduces the resource node.

Gradual wear of the hydraulic valve core leads to vibration during operation. In control and distribution units, vibration leads to ripple in the output stream. Increasing pressure in the cavity of the executive organs takes a pulsating nature, exacerbating the negative impact. Resonance of the surface from pulsation of hydraulic oil under high pressure ultimately leads to chipping and cracking of the surface.

The use of electro-magnetic valves and control pressure increases the likelihood of failure of the hydraulic system elements. Because the cross-section of the control channels of small diameter, the cold flow of hydraulic fluid cannot create the necessary control conditions. The created “back-up” of the cold fluid of the shuttle valves creates a not timely inclusion of the executive bodies. What can lead to emergency situations.

Modern machines with hydraulic equipment have different operating ranges of hydraulic fluid pressure, which determines the size of the cross sections of the channels of hydraulic lines and equipment. The most commonly used channel sizes are 1/2 '', 5/8 '', 3/4 '', 1 '', 1-1 / 2``, 1-3 / 4 ''. Adapters of any size for monoblock mounting are available for sale. But in order to exclude the effect of "throttling", it is necessary that the sections of the internal channels of the valve block correspond to the sections of the inlet and outlet openings of the hydraulic system. Therefore, it is impossible to manufacture a universal valve block. It is necessary to produce blocks for each of the aforementioned basic sizes of hydraulic systems of various machines.

The claimed device operates as follows. When the hydraulic fluid temperature is below -10 ° C, the control valve 1 is open, returning a pressure stream with a pressure above the maximum specified by the technical settings of the system through the safety valve 2 to the hydraulic tank 14 of the hydraulic system, the control valve 1 ensures the distribution of the fluid flow to the working one (for production machine tasks) with the necessary pressure and return to the hydraulic tank 14 with excess. Temperature control is carried out by a hydraulic fluid temperature sensor 15 installed in the hydraulic tank 14 and supplying a signal to the electrical circuit of the control relay 16, powered by the voltage of the main electrical circuit of the mining machine (24 volts). In the given conditions of the sensor resistances, the relay supplies voltage to the control valve coil 1.

As a result, the pressure of the hydraulic fluid, regardless of its temperature, will be maintained within the required limits. In addition, the return flow will accelerate the heating of the liquid.

At low hydraulic fluid temperatures, the valve block plays a damping role in the operation of the system. Cold liquid with sharp, jerky commands of control mechanisms commutes the increase in pressure and internal stress of parts in the system, because the fluid flow, sharply increasing in the system, does not leave the executive body to the same extent due to the difference in the density of the fluid. The heated liquid by the pump does not push the denser, colder portion previously in the actuator. This causes a hydraulic shock to the body of the organs.

The valve block, in turn, increases the potential for the release of hydraulic fluid again entering the system through a hydraulic pump (not shown in the drawings) - i.e., creates a temporary additional drainage line in the system.

Also, a softer operation is provided by the addition of a new structural element - nitrogen energy accumulator 13. It allows you to reduce the load with a pulsating hydraulic fluid supply. Such a load occurs in the event of malfunctions of the control valves of the main hydraulic pump or the block of flow distribution valves.

Nitrogen energy accumulator 13 will minimize the influence of parasitic factors in the most vulnerable operating modes. It must be installed in the system after the solenoid valve 1, controlled by means of a thermal relay. Accordingly, in front of the safety valve. To exclude the absorption of liquid energy during a heated stream to a working temperature above 0 ° C.

The working cavity of the energy accumulator must be filled with nitrogen, in order to ensure safety during operation of the machine. When a seal breaks between two cavities of the energy accumulator, mixing of substances occurs. When nitrogen and hydraulic fluid are mixed under pressure, ignition is not possible.

Claims (3)

1. A valve block comprising a control valve and a safety valve, wherein the inlet of the safety valve is connected to the outlet of the control valve, and the outlet of the safety valve is connected to a drain, characterized in that the control and safety valves are installed on the same platform, in the volume of which a figured a channel containing coaxial end portions provided with fittings and a channel parallel to them, connected by first and second branches lying in the same plane with the figured channel, the taps are continued by the first and second channels made before reaching the platform surface, and a third channel is made between the first and second channels, communicating the platform surface and the cavity of the figured channel, in addition, the first channel is made with the possibility of fixing in it, as a control, electromagnetic valve made with the possibility of overlapping the first outlet, while the second channel is made with the possibility of fixing in it a safety valve made with the possibility of overlapping the second outlet, and third th channel is fixable therein plugs or high-pressure hose fitting accumulator, in addition, the hydraulic reservoir mounted hydraulic hydraulic fluid temperature sensor adapted to supply a control signal to the solenoid valve. 2. The valve block according to claim 1, characterized in that the sections of the figured channel and the surface of the platform are parallel. 3. The valve block according to claim 1, characterized in that nitrogen is used as the working agent of the energy accumulator.

Images