RU2716521C1 - Piston device of pump - Google Patents

Abstract

FIELD: machine building.

SUBSTANCE: invention relates to hydraulic machines of positive displacement. Piston device comprises housing 1, crankshaft 2 installed in housing 1 with possibility of rotation around its axis of rotation and having at least one crankpin 21. First external gear wheel 5 is connected to crank shaft 2 with possibility of rotation together with the specified shaft. Second external gear wheel 6 is installed with possibility of engagement with the first external gear wheel 5. Proposed device comprises crank element 7, reciprocating piston 3 and piston engagement means of crank element 8. First external gear wheel 5 is connected with crankshaft 2 via eccentric 4 fitted on crankpin 21 of crankshaft 2. Connection means 8 comprises first part 81 in form of a rod connected to the piston, and second part 82 made bifurcated in the form of a fork. Branches 83 of fork 82 are installed in longitudinal guides 84 made in housing 1 with the possibility of back-and-forth movement. Second outer gear wheel 6 is located between branches 83 of connection means fork 82. Crank element 7 is installed eccentrically relative to axis of symmetry of the second gear wheel 6 and with possibility of rotation of the second gear wheel 8 around longitudinal axis 71 of the crank element. Opposite ends 72 of crank element 7 are installed in branches 83 of connection means fork 82.

EFFECT: simplified design.

1 cl, 3 dwg

Description

The invention relates to hydraulic machines for volume displacement; pumps for liquids or compressible fluids, namely, hydraulic volume displacement machines with rotating or oscillating working bodies.

Known piston metering pump (SU 530958, publ. 03/29/1977) containing a drive and a housing, a piston with sealing means, an additional piston pump with a drive is installed in the housing. In the pump housing there is a piston with sealing means and a drive providing reciprocating movement of the piston, for example, an eccentric. The drive of the auxiliary pump is rigidly connected with the drive of the main pump, made in the form of a cam, the profile of which ensures the movement of the piston of the additional pump ahead of the discharge phase relative to the piston of the main pump and the synchronous start of the suction stroke.

The disadvantage of this device is the design complexity that requires the use of several drives, the presence of large sliding friction forces resulting from the movement of the cam relative to the piston, which in turn leads to rapid wear of the mechanism elements. Also, the pump does not have the ability to control the piston stroke.

A known converter of rotational motion into translational (RU 2475665, publ. 02.20.2013), which consists of a housing and a fixed central gear wheel fixed therein, which is in gear engagement with a small gear of a double satellite. The small gear of the double satellite is rigidly connected with the large gear of the double satellite. The large gear of the double satellite is in gearing with the output satellite. The double satellite and the output satellite are mounted using rotational kinematic pairs in an asymmetric carrier, while their axis of rotation is parallel to the axis of rotation of the asymmetric carrier, which coincides with the axis of the stationary central gear.

The disadvantage of this device is the complexity and multi-link gear mechanism, providing reciprocating motion of the finger moving in the groove of the housing, which greatly complicates the adjustment of the fluid supply.

Known gear transducer of rotational motion to rotary (RU 2528493), consisting of a housing in which the input and output shafts of the central stationary gear wheel, rigidly mounted on the housing coaxially with the input shaft, an elliptical gear wheel eccentrically mounted on the output shaft, a satellite are coaxially mounted consisting of a cylindrical gear and an elliptical gear connected by a shaft, a carrier mounted on the input shaft connected to the other end through a rotational kinematic a pair with a satellite shaft. The central fixed gear is engaged with the spur gear of the satellite, and the elliptical gear of the gear is engaged with the elliptical gear. The central fixed gear consists of gearing with a cylindrical gear of a satellite of the same size as it is, the elliptical gear of the satellite consists of gearing with an elliptical gear of the same size, the elliptical gear of the satellite and the elliptical gear are mounted on their shafts in such a way that the axis rotation of the shaft passes through a point called the focus of the pitch ellipse of the elliptical gear or the elliptical gear of the satellite, which is located on the semimajor axis of the dividing ellipse at a distance from the center of the dividing ellipse.

The disadvantage of this device is the complexity of the design and the complexity of manufacturing non-circular gears, multi-link kinematic scheme, which includes two gears with a different number of teeth, as well as the inability to change the stroke length of the output link.

A reciprocating reciprocating device is known (patent RU 2623136), adopted for the prototype, which contains a housing-crankcase, a connecting rod having a large end and a small end, a crank element with a bearing block, and the crank element contains a gear wheel, which is the outer gear and is engaged with the gear, which is also the outer gear, the drive device for turning the gear relative to the crankcase around the axis of the shaft with a lock nym unit for fixation in various angular positions, the control ring and the actuator with a worm screw being in engagement with the worm gear.

A disadvantage of the known device is the complexity of its design, the presence of a large number of gears of different diameters and various gears. Moreover, in pairs of gear wheels that do not have a fixed center distance, it is practically impossible to provide the required lateral and radial clearances, which leads to increased gear wear, interference and jamming, and a decrease in the reliability of the entire piston device.

The basis of the present invention is to simplify the design of a piston device with a linear reciprocating movement of the piston by reducing the number of gears, and, as a result, to ensure the compactness of the piston device with the possibility of changing the stroke of the piston and transferring significant effort to the piston, and, in addition, increase the durability and reliability of the device.

The problem is solved in that in a piston device comprising a housing, a crankshaft mounted in the housing rotatably about its axis of rotation and having at least one connecting rod journal, a first outer gear connected to the crankshaft to rotate together with said shaft, a second outer gear mounted to engage with the first outer gear, a crank element, a piston reciprocating, media the connection of the crank element with the piston, according to the invention, the first outer gear is connected to the crankshaft via an eccentric mounted on the neck of the crankshaft, the coupling means comprises a first part in the form of a rod connected to the piston and a second part made forked in the form of a fork, the fork branches are installed in longitudinal guides made in the housing with the possibility of reciprocating motion, the second outer gear is located between the branches of the fork compound va, a crank member is mounted eccentrically with respect to the symmetry axis of the second gear and with the possibility of rotation of the second gear about the longitudinal axis of the crank member, the opposite ends of the crank member mounted in the fork branches connecting means.

To convert the rotational motion of the crankshaft into a reciprocating linear motion of the piston in the proposed device, only two gear wheels are used, which simplifies the design of the piston device, ensures its compactness with the possibility of transferring significant forces to the piston, and, in addition, to increase the durability and reliability of operation devices.

The installation of the first and second gears with an eccentricity with respect to their centers of symmetry, namely, the axis of rotation of the crankshaft with the first gear and the longitudinal axis of the crank element with the second gear, provides a complex rotational-translational movement of the centers of the gears in the plane of their engagement.

The ability to rotate the second gear around the longitudinal axis of the crank element provides reciprocating movement of the longitudinal axis of the crank element and the linear stroke of the piston connecting to the crank element with the fork branches of the connecting means in the housing guides.

It is advisable that the eccentric be mounted on the neck of the crankshaft with the possibility of rotation around the axis of the neck of the crankshaft and fixation in various angular positions relative to the specified axis.

The ability to rotate the eccentric and fix it in various angular positions relative to the neck of the crankshaft, allows you to create the desired total eccentricity of the first gear relative to the axis of rotation of the crankshaft and thereby set the desired piston stroke.

It is advisable to perform the crank element in the form of a rod or finger.

This embodiment of the crank element is structurally simpler to ensure that the crank element is connected to the second gears and fork branches of the coupling means.

It is advisable that the first and second outer gears each be mounted on a cylindrical roller, in which the outer diameter is equal to the initial diameter of the gear put on it.

The rollers of the first and second gears provide a guaranteed radial clearance in the engagement of the latter. Due to the fact that the diameters of the rollers are equal to the initial diameters of the gears, these rollers run on each other without sliding, ensuring a constant center distance in the meshing of the gears with a complex rotational-translational movement of their centers in the plane of engagement.

It is advisable that the first and second gears have the same number of teeth.

An equal number of teeth ensures the same piston stroke per revolution of the drive shaft and, as a result, a stable pump flow.

It is advisable that the crank element was fixedly mounted on the roller of the second gear wheel, while the ends of the crank element are fixed in the branches of the fork through the bearing mechanism with the possibility of rotation of the ends of the crank element relative to the branches of the fork.

The fastening of the ends of the crank element in the branches of the fork through the bearing mechanism allows to reduce the resistance to movement of the crank element around its axis in the branches of the fork and to increase the efficiency of the piston device of the pump as a whole, to reduce the wear rate of the crank element and the branches of the fork in their interface and, as a result, to increase the durability and reliability of the piston devices.

According to another embodiment, a similar effect can be achieved by movably fastening the crank element on the rink of the second gear wheel through the bearing mechanism, while the ends of the crank element are fixedly fixed in the branches of the yoke of the coupling means.

It is advisable that the branches of the plug means of connection were installed in the guides of the housing through the bearing mechanism.

Bearing connections between the branches of the fork and the guides of the housing can reduce the resistance to movement of the branches of the fork in the guides, one hundred provides an increase in the efficiency of the piston device of the pump as a whole, a decrease in the wear rate of the guides and branches of the fork and, as a result, an increase in the durability and reliability of the piston device.

It is advisable that the piston device contains means for compressing the second gear to the first one, made in the form of a spring mounted on the first rod part of the connecting means, with one end of the spring mounted on the housing and the other resting on the base of the second forked part of the connecting element.

The specified tool provides a constant preload of the first and second gears between them.

It is advisable that the device was equipped with means for controlling the stroke of the piston, including a mechanism for turning the eccentric relative to the neck of the crankshaft.

The presence of such a tool allows the eccentric to rotate by a predetermined angle to create the required piston stroke equal to the vector sum of the eccentricities of the neck of the crankshaft, the eccentric of the first gear and the eccentricity of the second gear relative to the axis of the crank element.

In the future, the alleged invention will be described in more detail with specific examples of its implementation with reference to the drawings in which are depicted;

FIG. 1 is a general view of a plunger pump, a longitudinal section;

FIG. 2 is a section AA in FIG. 1;

FIG. 3 is a cross-section BB in FIG. 2;

The piston device shown in the figures contains a housing 1 (Fig. 1), a crankshaft 2 mounted in the housing 1 with the possibility of rotation around its axis of rotation, the piston 3.

On the crankshaft 2 through the eccentric 4 is installed, with the possibility of rotation together with the specified shaft 2, the first outer gear 5.

The eccentric 4 is mounted on the crank pin 21 of the crankshaft 2 with the possibility of rotation around the axis of the neck of the crankshaft and fixation in various angular positions relative to the specified axis.

The device comprises a second outer gear 6, which is in mesh with the first outer gear 5 in the working position of the device. Hereinafter, for ease of presentation, the first and second outer gears 5 and 6 will be designated as the first and second gears 5 and 6, respectively.

In a preferred embodiment, the first and second gears 5 and 6, respectively, are each mounted coaxially on the cylindrical roller 51 and 61, the outer diameter of each roller 51 and 61 being equal to the initial diameter of the gear 5 and 6 worn on it.

It is possible to implement the device without these rollers, as well as with another device to provide the required lateral and radial clearance between the gears.

Also in a preferred embodiment, the first and second gears 5 and 6, respectively, have the same number of teeth. However, it is possible to implement a pumping device with a different number of teeth in the gears. In this case, the piston stroke will change cyclically when the first gear is rotated, and the magnitude of this cycle will be determined by the gear ratio of the pair of gears.

A crank element 7 is mounted on the roller 61 of the second gear 6 eccentrically relative to the axis of symmetry of the roller 61.

The crank element 7 is made bilateral in the form of a rod or finger, the longitudinal axis 71 (Fig. 2) of which is parallel to the axis of symmetry of the second gear 6 and is the axis of rotation of the second gear 6.

Perhaps fixing the crank element 7 directly to the gear wheel 6.

The crank element 7 is connected to the piston 3 by means of the connection 8 made with the possibility of reciprocating movement of the piston 3 from the crank element 7.

The connection means 8 comprises a first part 81 in the form of a rod connected to the piston 3 and a second part 82 made in the form of a fork with two branches 83. The branches 83 of the fork 82 are mounted in the longitudinal guides 84 with the possibility of reciprocating motion. The guides 84 are made on the side walls of the housing 1 of the piston device.

Hereinafter, for simplicity of presentation, the same position 81 will be used for the "first part of the connecting element" and the "rod", and the same position 82 will be used for the "second part of the connecting element" and "plug".

The opposite ends 71 of the crank element 7 are installed in the branches 83 of the fork 82.

According to one embodiment of the piston device, the crank element 7 is fixedly mounted on the roller 61 of the second gear wheel 6 (or on the gear wheel 6 itself), for example, is pressed into it. The ends 72 of the crank element 7 are fixed in the branches 83 of the yoke 82 through the bearing mechanism 85, as shown in FIG. 2. As the bearing mechanism, sliding bearings or rolling bearings - ball, roller, needle, etc. can be used.

According to another embodiment of the piston device, the crank element 7 is mounted on the roller 61 of the second gear 6 (or on the gear 6 itself) through the bearing mechanism 86, while the ends of the crank element 72 are fixedly fixed in the branches 83 of the yoke 82 of the connecting element 8, for example, are pressed in them. (Fig. 3.). In this case, ball or roller bearings can be used as a bearing mechanism.

In both versions, the bearing mechanisms 85 and 86 rotate the second gear 6, which is meshed with the first gear 5, about the longitudinal axis 71 of the crank element 7 and the linear stroke of the piston 3 together with the crank element 7 connected to it by the branches 83 of the fork 82 in guides 84 of the housing 1.

The branches 83 of the yoke 82 of the coupling means 8 are installed in the guides 84 of the housing 1 through the bearing mechanism 87, for example, linear plain bearings or rolling bearings, roller or needle, and also their elements - rolling elements, for example rollers.

Bearing mechanisms 87 and 85, 86 reduce mechanical resistance along the path of the reciprocating movement of the branches 83 of the yoke 82 in the guides 84 and the rotational movement of the crank element 7 around its axis in the branches 83 of the yoke or / and in the roller 61 and thereby reduce the wear rate of the elements piston device, and also can improve the durability, reliability and efficiency of the piston device.

The piston device comprises means 9 for compressing the second gear 6 to the first 5, made in the form of a compression spring mounted on the first shaft portion 81 of the connection means 8. One end of the spring of the preloading means 9 (hereinafter referred to as the spring 9) is fixed to the housing 1, and the other rests on the base of the second bifurcated part 82 of the connecting means 8.

In this case, in its normal state, the compression spring has a preliminary compression.

It is possible another implementation of the specified means of preload, for example, the specified tool may contain magnets, rollers or other devices. In addition, in individual designs, when the piston is subject to constant pressure from the pumped medium, it is possible to implement the piston device without the specified means of preload.

In a preferred embodiment, the piston device comprises means 10 for regulating the stroke of the piston, including a mechanism 101 for turning the eccentric 4 relative to the neck 21 of the crankshaft 2. Possible various embodiments of the said mechanism 101 for turning, for example, it can be made in the form of a helicoidal nut fixed to an eccentric and helicoidal rod with axial power drive.

The piston device operates as follows.

To set the required stroke of the piston 3 of the piston device by the eccentric rotation mechanism 101, turn the eccentric 4 to the desired angular position, thereby forming the desired total eccentricity of the first gear 5 relative to the axis of rotation of the crankshaft 2. Performing rotational movement together with the crankshaft 2, which is the drive , the first gear 5, due to gear engagement with the second gear 6, drives the latter into rotation about the longitudinal axis 72 of the crank element 7.

The spring 9 on the first, rod portion 81 of the connection means 8 presses the gears 5 and 6 against each other. Since the spring 9 in its normal state has a preliminary preload, the preload of the gears 5 and 6 is carried out both with the forward and reverse strokes of the piston 3, while at the end of the forward stroke the compressive force will be greater than at the end of the reverse stroke of the piston 3.

The rollers 51 and 61 of the gears 5 and 6 provide a guaranteed radial and lateral clearance in the engagement of the teeth of the gears 5 and 6, preventing tooth interference. In addition, due to the fact that the diameters of the rollers 51 and 61 are equal to the initial diameters of the gears 5 and 6, the rollers 51 and 61 run on each other without sliding, ensuring a constant center distance in engagement.

Moreover, the centers of the gears 5 and 6 in the plane of engagement carry out a complex rotational-translational motion. This movement of the centers of the gears 5 and 6 is due to the eccentricity of the installation of these gears relative to their centers of rotation, namely, the axis of rotation of the crankshaft 2 with the first gear 5 and the longitudinal axis of the crank element 7 with the second gear 6, respectively.

The center of the second gear 6 moves along the arc up and down, while simultaneously rotating around the longitudinal axis of the crank element 7. The eccentricity of the crank element 7 determines the amplitude of the movement of the center of symmetry of the second gear 6. In this case, the longitudinal axis of the crank element 7 makes a reciprocating motion.

In the embodiment shown in FIG. 2, the crank element 7 together with the gear 6 rotates around the longitudinal axis 71 of the crank element relative to the branches 83 of the yoke 82.

In the embodiment shown in FIG. 3, the second gear 6 rotates around the longitudinal axis of the crank element 7 and relative to the fork 82 with the crank element 7 rigidly mounted therein.

The movable connection of the crank element 7 through the bearing mechanisms 85 or 86 on the one hand, and the movable connection of the branches 83 of the yoke 82 with the longitudinal grooves 84 of the housing 1 provide linear reciprocating movement of the first, rod, part 81 of the coupling means 8 and the piston 3 connected to it. The magnitude of the stroke of the piston 3 is equal to the double vector sum of the distances from the geometric centers of the gears 5 and 6 to the actual points of their rotation, determined with the corresponding eccentricities.

If necessary, change the magnitude of the stroke of the piston 3 during operation of the piston device, regardless of the rotation of the crankshaft 2, by means of the eccentric rotation mechanism 101, turn the eccentric 4 around the neck 21 of the crankshaft 2 to the desired angular position, thereby forming the desired total eccentricity of the first gear 5 relative to axis of rotation of the crankshaft 2.

The above examples of the preferred embodiment of the invention, containing indications of individual embodiments, do not exhaust the possible changes and additions that are obvious to a person skilled in the art, which do not affect the essence of the technical solution described by the claims.

Claims (10)

1. A piston device comprising a housing, a crankshaft mounted in the housing rotatably about its axis of rotation and having at least one crank pin, a first outer gear connected to the crankshaft rotatably together with said shaft, a second outer gear a wheel mounted with the possibility of engagement with the first outer gear, a crank element, a piston made with the possibility of reciprocating movement, means for connecting the crank element a piston, characterized in that the first external gear wheel is connected to the crankshaft through an eccentric mounted on the neck of the crankshaft, the connecting means comprises a first part in the form of a rod connected to the piston, and a second part made forked in the form of a fork, while the fork branches mounted in longitudinal guides made in the housing with the possibility of reciprocating motion, the second external gear wheel is located between the branches of the fork means of the connection, the crank element is mounted eccentric ary relative to the axis of symmetry of the second gear and the second rotatable gear about the longitudinal axis of the crank member, the opposite ends of the crank member mounted in the fork branches connecting means. 2. The piston device according to claim 1, characterized in that the eccentric is mounted on the neck of the crankshaft with the possibility of rotation around the axis of the neck of the crankshaft and fixation in various angular positions relative to the specified axis. 3. The piston device according to claim 1, characterized in that the crank element is made in the form of a rod or finger. 4. The piston device according to claim 1, characterized in that the first and second outer gears are each mounted on a cylindrical roller, while the outer diameter of each roller is equal to the initial diameter of the gear wheel put on it. 5. The piston device according to claim 1, characterized in that the first and second gears have the same number of teeth. 6. The piston device according to claim 1, characterized in that the crank element is fixedly mounted on the roller of the second gear wheel, while the ends of the crank element are fixed in the branches of the fork through the bearing mechanism with the possibility of rotation around the longitudinal axis of the crank element. 7. The piston device according to claim 1, characterized in that the crank element is movably fixed to the roller of the second gear wheel through the bearing mechanism, while the ends of the crank element are fixedly fixed in the branches of the fork of the connecting element. 8. The piston device according to claim 1, characterized in that the branches of the plug of the connecting element are installed in the guides of the housing through a bearing mechanism. 9. The piston device according to claim 1, characterized in that it comprises means for compressing the second gear to the first gear, made in the form of a spring mounted on the first part of the connecting means, while one end of the spring is fixed to the housing and the other rests on the base of the second bifurcated part means of connection. 10. The piston device according to claim 2, characterized in that it is provided with means for controlling the stroke of the piston, including a mechanism for turning the eccentric about the axis of the neck of the crankshaft.

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