RU2450173C1 - Pressure multiplier - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: multiplier is designed to transfer power of the working fluid with conversion of its pressure, particularly in hydraulic drives of presses (forging presses, stamping presses, etc.) and testing equipment (e.g., machines of pipe hydraulic testing). The multiplier consists of housing 1 in the form of a sleeve with internal central support seal band. It contains piston hydraulic cylinders of low and high pressure and a kicker hydraulic cylinder. Housing 1 is closed with no-go lids 2 and 3 on its ends. Housing 1 has power piston 4 of a permanent operating diameter forming working spaces 5 and 6 of low and high pressure respectively. Housing 7 of the kicker hydraulic cylinder is located coaxially with power piston 4, rigidly connected to lid 3, located on the side of high pressure chamber 6 and enters boring of power piston 4 with formation of drain cavity 8 where piston 9 of the kicker hydraulic cylinder enters. Piston 9 may be spring-actuated relative to housing 7 by means of compression spring 10 installed in working chamber 11 of the kicker hydraulic cylinder.

EFFECT: reduced size and weight of the unilateral pressure multiplier.

2 cl, 1 dwg

Description

The invention relates to the field of hydraulic equipment, namely to pressure multipliers, and can be used in any hydroficated equipment for transmitting energy of a working fluid with conversion of its pressure, in particular, in hydraulic drives of presses (forging, stamping, etc.) and test equipment (for example machines for hydraulic testing of pipes).

Known pressure multiplier single acting, containing plunger hydraulic cylinders of low and high pressure and a return cylinder, plungers and casings of which are interconnected to form a closed power circuit, while the hydraulic cylinders of low and high pressure are coaxial [1]. To ensure the return of the plungers of the low and high pressure cylinders to the initial position, there are two return hydraulic cylinders in the design of the multiplier, the working cavities of which are constantly connected to the low pressure pressure hydraulic line (to which the working cavity of the low pressure hydraulic cylinder is connected to provide the working stroke of the multiplier). The effective area of the plungers of the return hydraulic cylinders is selected for reasons of the most economical (from an energy point of view) expenditure of low-pressure fluid during the reverse stroke of the multiplier.

For the pressure multiplier under consideration, the plungers of the low and high pressure cylinders rigidly connected to each other have different diameters, as a result of which the size of the multiplier in its axial direction cannot be less than the triple value of the plunger stroke of each of these cylinders.

The return hydraulic cylinders are located symmetrically with respect to the axis of the low and high pressure hydraulic cylinders, while the axes of all hydraulic cylinders are parallel and lie in the same plane. The presence of returnable hydraulic cylinders located on the sides of the high-pressure hydraulic cylinder increases the transverse dimensions of the multiplier.

To ensure the connection of plungers and cases of hydraulic cylinders that are part of the multiplier with the formation of a closed power circuit, additional parts are used (in particular, movable and fixed traverses), which increases the mass of the multiplier.

Thus, the existing pressure multiplier is characterized by increased longitudinal and transverse dimensions, as well as increased mass, which are the disadvantages of its design.

The design of the multiplier has four movable pairs that separate the working cavity of the hydraulic cylinders included in it from the atmosphere. The seals of these moving pairs during wear of the multiplier are subject to wear. If the seals of any of the moving pairs of the multiplier are broken, the working fluid enters the environment, which leads to the loss of the working fluid and, in most cases (except when water is used as the working fluid), to environmental pollution. Both noted circumstances are negative.

The closest in technical essence to the claimed object is a single-acting pressure multiplier adopted as a prototype, comprising low and high pressure plunger hydraulic cylinders and a return hydraulic cylinder, the plungers and bodies of which are interconnected to form a closed power circuit, while the low and high pressure hydraulic cylinders are located coaxially [2]. In this multiplier, the plunger of the low-pressure hydraulic cylinder is at the same time a movable body of the high-pressure hydraulic cylinder, the plunger of which is made stationary. Due to this, the size of the multiplier in its axial direction can be very close to twice the stroke of the plunger of the low pressure hydraulic cylinder, that is, to the minimum achievable longitudinal dimension of the design of the single-acting pressure plunger multiplier.

However, to ensure the return of the plunger of the low-pressure hydraulic cylinder (the movable housing of the high-pressure hydraulic cylinder) to the initial position, there are two return hydraulic cylinders in the construction of the multiplier, the working cavities of which are connected to the drain during the working stroke of the multiplier and with a low pressure hydraulic line during the reverse stroke (for switching cavities of return hydraulic cylinders with a drain and with a low pressure hydraulic line requires an additional control valve) or are constantly connected to molecular weight low pressure hydraulic line (which for the stroke is connected to the multiplier and the low-pressure working chamber of the hydraulic cylinder). Regardless of which of the indicated options for connecting the cavities of the return hydraulic cylinders is used during the working stroke of the multiplier, the effective area of the plungers of the return hydraulic cylinders is chosen so that, on the one hand, the force created by the return hydraulic cylinders when connecting their working cavities with a low pressure hydraulic line, was enough to return the moving parts of the multiplier with a given speed to its original position (corresponding to the beginning of the working stroke of the multiplier), and with on the other hand, in the process of returning the moving parts of the multiplier to its original position, the minimum possible volume of low-pressure liquid was consumed.

The return hydraulic cylinders are located symmetrically with respect to the axis of the low and high pressure hydraulic cylinders, while the axes of all hydraulic cylinders are parallel and lie in the same plane. The presence of returnable hydraulic cylinders located on the sides of the low and high pressure hydraulic cylinders increases the transverse dimensions of the multiplier. To ensure the connection of plungers and cases of hydraulic cylinders that are part of the multiplier with the formation of a closed power circuit, additional parts are used (in particular, movable and fixed traverses), which increases the mass of the multiplier.

As a result, the known pressure multiplier is characterized by increased transverse dimensions, as well as mass, which are the disadvantages of its design.

The design of the multiplier has four movable pairs that separate the working cavity of the hydraulic cylinders included in it from the atmosphere. The seals of these moving pairs during wear of the multiplier are subject to wear. If the seals of any of the moving pairs of the multiplier are broken, the working fluid enters the environment, which leads to the loss of the working fluid and, in most cases (except when water is used as the working fluid), to environmental pollution. Both noted circumstances are negative.

The technical problem solved by the invention is to reduce the size and mass of the pressure multiplier single-acting, containing plunger hydraulic cylinders of low and high pressure and a return cylinder.

An additional technical objective of the invention is to provide the possibility of operating the multiplier for any vertical location of its axis.

To solve the technical problem in the well-known single-acting pressure multiplier containing plunger hydraulic cylinders of low and high pressure and a return cylinder, plungers and casings of which are interconnected to form a closed power circuit, while the hydraulic cylinders of low and high pressure are coaxial, according to the invention, hydraulic cylinder plungers low and high pressure are made in the form of one power plunger of constant working diameter, which is installed in the housing, with t Ortsov closed with impassable covers and having the appearance of a sleeve with an inner central support and sealing girdle, with the formation of working cavities of low and high pressure, and the return hydraulic cylinder is located coaxially with the power plunger and its body is rigidly connected to the cover located on the side of the high pressure cavity and is included in the bore of the power plunger with the formation of a drainage cavity into which the plunger of the return hydraulic cylinder enters.

According to the invention, the plunger of the return hydraulic cylinder is spring-loaded relative to its body.

The execution of the plungers of hydraulic cylinders of low and high pressure in the form of one power plunger of constant working diameter, which is installed in the housing, with ends closed by passage covers and having the form of a sleeve with an inner central support and sealing girdle, with the formation of working cavities of low and high pressure, as well as the location the return hydraulic cylinder coaxial to the power plunger and the rigid connection of its body with a cover located on the side of the high-pressure cavity, with the power a lunger with the formation of a drainage cavity into which the plunger of the return hydraulic cylinder enters, allows reducing the dimensions of the multiplier in its transverse direction to the transverse dimensions of the low-pressure hydraulic cylinder and practically eliminating additional details (primarily traverses) from the design of the multiplier to ensure the connection of the plungers and cylinder bodies, included in the multiplier, with the formation of a closed power circuit. Due to this, ceteris paribus, both the mass of the multiplier as a whole and the mass of its moving parts decrease. A decrease in the mass of moving parts has a positive effect on the dynamic characteristics of the multiplier.

The execution of the plunger of the return hydraulic cylinder spring-loaded relative to its body allows the multiplier to be operated at any vertical location of its axis (i.e., when the multiplier is installed by the plunger of the return hydraulic cylinder both down and up).

The invention is illustrated in the drawing, which shows a structural diagram of the pressure multiplier.

The pressure multiplier consists of a housing 1 having the form of a sleeve with an inner central support and sealing girdle. At the ends, the housing 1 is closed by impassable covers 2 and 3. In the housing 1, a power plunger 4 of constant working diameter is installed with the formation of working cavities 5 and 6, respectively, of low and high pressure.

The housing 7 of the return hydraulic cylinder is located coaxially with the power plunger 4, is rigidly connected to the cover 3, located on the side of the high-pressure cavity 6, and enters the bore of the power plunger 4 with the formation of a drainage cavity 8 into which the plunger 9 of the return hydraulic cylinder exits.

The plunger 9 can be spring-loaded relative to the housing 7 using a compression spring 10 installed in the working cavity 11 of the return hydraulic cylinder. The spring 10 serves to ensure constant guaranteed contact of the end face of the plunger 9 with the plunger 4 in those cases when the multiplier during operation is installed upward by the plunger 9.

The movable pairs formed by the power plunger 4 and the housing 1, the plunger 9 and the housing 7 of the return hydraulic cylinder, the plunger 4 and the housing 7, are sealed with seals 12, 13, 14, respectively.

The connection of the cavities 5, 6, 8, 11 with external hydraulic lines (not shown in the drawing) is carried out through the holes 15, 16, 17, 18, respectively, made in the housing parts of the multiplier.

The diameter of the plunger 9 of the return hydraulic cylinder is selected so that, on the one hand, the pressure force of the fluid on the plunger 9, created when the working cavity 11 of the return hydraulic cylinder is connected to the low pressure hydraulic line (not shown in the drawing), is sufficient to return the moving parts (plungers 4 and 9) a multiplier with a given speed in the initial position (corresponding to the movement of the power plunger 4 all the way into the cover 2), and on the other hand, in the process of returning the moving parts of the multiplier to its original position the lowest possible volume of low-pressure fluid was consumed.

The diameter of the outer working cylindrical surface of the housing 7 of the return hydraulic cylinder is selected from the condition of ensuring a given multiplier of the multiplier (taking into account what the working cavity 11 of the return hydraulic cylinder is connected to during the working stroke of the multiplier: with a drain or with a low pressure hydraulic line with which to carry out the working stroke the multiplier is connected and the cavity 5 low pressure).

Obviously, the diameter of the working surface of the power plunger 4 is larger than the diameter of the outer working cylindrical surface of the housing 7 of the return hydraulic cylinder, and that in turn is larger than the diameter of the plunger 9.

The multiplier works as follows.

To carry out the working stroke, the low-pressure cavity 5 is connected through an opening 15 with a low-pressure hydraulic line (not shown in the drawing), the high-pressure cavity 6 through an opening 16 - with a consumer of high-pressure liquid (not shown), and the cavity 11 of the return hydraulic cylinder through an opening 18 - with a low pressure hydraulic line or with a drain (depending on the design of the hydraulic system, which uses a multiplier).

When installing the multiplier with the plunger 9 of the return hydraulic cylinder upward and connecting the cavity 11 to the drain, the constant contact of the plunger 9 with the power plunger 4 is provided using a spring 10.

Under the action of the low-pressure fluid, the power plunger 4 moves in the direction of the high-pressure cavity 6, forcing the high-pressure fluid out of it through the opening 16 to the consumer (not shown in the drawing). In this case, the plunger 9 of the return hydraulic cylinder moves together with the power plunger 4, displacing the liquid from the cavity 11 through the hole 18 to the drain or into the low pressure hydraulic line (depending on what the cavity 11 is connected to during the working stroke).

To carry out the return stroke, the low pressure cavity 5 is connected through a hole 15 with a drain, the high pressure cavity 6 through the hole 16 is connected to a feed tank (not shown in the drawing), and the cavity 11 of the return hydraulic cylinder through the hole 18 is connected to a low pressure hydraulic line (if cavity 11 not permanently connected to the low pressure hydraulic line).

Under the action of low-pressure liquid, the plunger 9 of the return hydraulic cylinder extends from its body 7. At the same time, the power plunger 4 moves together with the plunger 9 of the return hydraulic cylinder, displacing the liquid from the low-pressure cavity 5 through the hole 15 to the drain, and the high-pressure cavity 6 increases in volume and It is filled with working fluid from a nutrient tank.

Cases 1, 7, covers 2, 3 and fasteners connecting them (fasteners are not shown in the drawing), as well as plungers 4, 9 together form a closed power circuit. The liquid pressure forces that arise in this circuit during the operation of the multiplier at steady-state conditions are practically not transmitted to the multiplier supports (the supports are not shown in the drawing). That is, in the proposed design, a closed power circuit is obtained without the use of any additional parts (such as traverse), so that, ceteris paribus, the multiplier has smaller dimensions and weight compared to the prototype.

The multiplier under consideration has three moving pairs. In this case, possible leaks of the working fluid from the cavities 6 and 11 through the movable pairs sealed with seals 14 and 13 fall into the drainage cavity 8 and are discharged from the latter through the opening 17 along the drainage hydraulic line into the feed tank (the drainage hydraulic line and feed tank are not shown in the drawing) . Possible overflow of working fluid between cavities 6 and 5 through a movable pair sealed with a seal 12 also remains inside the hydraulic system, in which a multiplier is used.

Thus, the proposed multiplier, as follows from the above description of its design and operation, not only is characterized by reduced dimensions and weight, but also additionally eliminates the loss of working fluid through movable vapors into the environment in case of violation of the tightness of the corresponding seals.

The multiplier can be used in any hydroficated equipment to transfer the energy of the working fluid with the conversion of its pressure, in particular, in hydraulic drives of presses (forging, stamping, etc.) and testing equipment (for example, machines for hydraulic testing of pipes).

Literary sources

1. Kornilov V.V., Sinitsky V.M. Hydraulic drive in forging equipment: textbook for universities / Ed. N.V. Pasechnik. M .: Mechanical Engineering, 2002 .-- 224 p. (p.175, fig. 92).

2. Dobrinsky N.S. Hydraulic drive presses. M.: Mechanical Engineering, 1975 .-- 222 p. (p. 91, fig. 43).

Claims (2)

1. The pressure multiplier single acting, containing plunger hydraulic cylinders of low and high pressure and a return cylinder, the plungers and housings of which are interconnected to form a closed power circuit, while the hydraulic cylinders of low and high pressure are coaxial, characterized in that the plungers of low and high hydraulic cylinders the pressure is made in the form of a single power plunger of constant working diameter, which is installed in the housing, from the ends closed by impassable covers and having the form of gills s with an inner central support-sealing girdle, with the formation of working cavities of low and high pressure, and the return hydraulic cylinder is located coaxially to the power plunger and its body is rigidly connected to the cover located on the side of the high-pressure cavity, and enters the bore of the power plunger with the formation of a drainage cavity into which the plunger of the return hydraulic cylinder enters. 2. The pressure multiplier according to claim 1, characterized in that the plunger of the return hydraulic cylinder is spring-loaded relative to its body.