RU2756825C1 - Rotary-plate device for converting reciprocating motion into rotational motion without crank mechanism - Google Patents

Abstract

FIELD: rotary equipment.

SUBSTANCE: rotary-plate device is designed to convert reciprocating motion into rotational motion without using a crank mechanism. The rotary-plate device can be used as either a pump, or a compressor, or a hydraulic pneumatic drive, or a silent vacuum cleaner. The rotary-plate device includes stator (2), brackets with support rollers, side covers, rotor (1), and at least two piston plates (8). Stator (2) has a cylindrical shape with inlet and outlet (6), (6'). Brackets with support rollers move on the outer surface of stator (2). Side covers are made with annular grooves. Rotor (1) is located non-coaxially relatively to stator (2) to form chambers of unequal volume. Rotor (1) is made with at least two radial grooves. At least two piston plates (8) are installed in radial grooves with the possibility of reciprocating motion. Working piston plates (8) have a length greater than the length of rotor (1) body, protruding from rotor grooves. Working piston plates (8) enter radial grooves of support disks installed on both sides of rotor (1) so that grooves of support disks coincide with rotor grooves. Working piston plates (8), leaving grooves of rotor (1) as much as possible, remain in grooves of support disks. For tightness, additional seal is inserted into radial grooves. Annular grooves in side covers are used to distribute the pressure that occurs under plates, and are made at the level of radial grooves located in the rotor.

EFFECT: increase in the tightness, as well as an increase in the useful internal volume and service life of the device.

3 cl, 7 dwg

Description

There is a known method of moving liquid and gaseous media using a piston device, the movement of the piston in the cylinder of which is carried out using a crank mechanism that converts the reciprocating movement of the piston into rotational and vice versa. Along with all the known advantages, the device has one serious drawback, the crank mechanism. The mechanism is quite complex in terms of technology and dramatically increases overall dimensions with an increase in useful volume.

The proposed invention makes it possible to convert the reciprocating movement of the piston plates in the rotor slots, with constant contact with the inner surface of the stator, without using the crank mechanism. The invention makes it possible to use the rotational movement of the rotor, which will cause the reciprocating movement of the plate-pistons and lead to the movement of the medium.

The force of the expanding medium, F, presses on the piston, which is connected to the connecting rod fixed on the crank, see FIG. 1 with a clear illustration of the conversion of the piston reciprocating motion into rotary motion by the crank.

The invention is proposed for converting the reciprocating motion of pistons (plates) into rotational, due to the movement of pistons (plates), in constant contact with the inner surface of the stator, without a crank mechanism.

DESCRIPTION OF THE INVENTION:

Force F presses on the piston plate, pushing it out of the rotor slot, transferring the force to the support roller (I). Since the center of rotation of the rotor is displaced relative to the center of rotation of the rotor, the roller of the piston plate (II) will roll over the stator surface (III), and the piston plate will rotate the rotor body (IV) (see Fig. 2).

The force of the expanding medium F, presses on the surface of the adjacent piston plates. Since the area of one plate pulled out of the slot is larger than the previous one, the force F will press on the surface of the plate, forcing it to move out of the slot. Due to the connection of the piston plates with the outer surface of the stator, the rotor will begin to turn. Thus, the reciprocating movement of the piston plates will be converted into a rotational movement of the rotor. The method allows converting the rotational movement back into the reciprocating movement of the plate-pistons (see Fig. 3).

A device that converts reciprocating motion into rotational motion.

Lever-rotor device

Levertor device, from the English word LEVER - lever, and ROTOR - impeller, LEVEROTOR - rotation of the impeller by the gate.

The invention relates to the field of mechanical engineering and can be used as a hydraulic pneumatic drive, in the form of a compressor or pump, a water jet and silent vacuum cleaners.

Known rotor-plate device (patent No. RU 2541059). The device contains a stator, a rotor located in it with radial grooves and working plates in them, installed with the possibility of reciprocating movement and contact with its upper parts with the inner surface of the stator housing. The stator housing is cylindrical and has side covers with an annular groove. The rotor is disposed coaxially with an offset to the wall of the housing to form chambers of unequal volume, with each plate made with protrusions contacting the annular groove of the covers to ensure angular movement of the upper part of the plate in constant contact with the inner surface of the housing.

The disadvantage of this device is that the plates, in contact with their upper parts with the inner surface of the stator, have only linear contact along the axial surface. This does not create the desired tightness. The plates, moving in the radial grooves of the rotor, have a limitation on the maximum exit from the groove, since at the maximum exit, there will be a strong mechanical load on the edges of the groove, and the plate can destroy the edges of the groove. And also, the gap between the upper parts and the inner surface of the stator is not adjusted during wear, which also leads to leakage.

The objective of the proposed solution is to create a universal rotor-plate device for use, simple to manufacture and reliable in operation.

The technical result of the proposed solution is to increase the tightness, as well as to increase the useful internal volume and service life of the device, which ensures greater efficiency of the device.

The tightness is increased due to the constant, adjustable optimal contact of the rotor plates with the inner surface of the stator.

The increase in the useful internal volume is carried out due to the maximum exit of the piston plates from the rotor slot.

Increase in the service life of the device due to the fact that the mechanical load on the edges of the radial grooves is reduced due to the use of sealing plates located on the inner surface of the stator, due to which the restrictions on the maximum exit of the piston plates from the radial grooves are removed and the mechanical load on the outer edges of the radial grooves is reduced.

To achieve the specified technical result in a leverotor device containing a stator, a rotor misaligned in it with at least two radial slots, and working piston plates in them, at least one in each slot, installed with the possibility of reciprocating movement and contacting when Moreover, with its upper parts with the inner surface of the sealing plates having the same inner radius of curvature as the outer edge of the working piston plates, and the outer edge of the sealing plates has the same radial curvature as the inner surface of the stator housing. The outer surface of the sealing plates and the side surface of the working piston plates may have longitudinal grooves into which additional seals are inserted. According to the proposal, the outer edges of the stator housing have a cylindrical shape, along which the support rollers or rollers move, having an adjustable, mechanical connection through brackets, with internal sealing plates, which, in turn, are hingedly connected to the working piston plates moving in the rotor slots ... The working piston plates have a length greater than the length of the rotor body, protruding from the rotor slots, and enter the radial slots of the supporting discs installed on both sides of the rotor so that the slots of the supporting discs coincide with the rotor slots, and the working piston plates, leaving from the slots of the rotor, as much as possible, remained in the slots of the supporting discs. Thus, the tightness of the chambers between the working piston plates is ensured, with the maximum exit of the main plates from the rotor slots, and there is no load that can destroy the edges of the rotor slots. In the supporting discs, annular grooves are made at the level of the bottom of the rotor slot, serving to distribute the pressure that occurs under the plates. In the case of using the device as a pump or compressor, the number of working plates in the groove can be more than one, and the sub-plate space can be filled with a special sealing grease. Inlet and outlet openings are made in the stator body to supply and remove the pumped medium.

Also, according to the proposal, blind axial holes are made on the rotor shaft from one end, having an exit into the grooves.

The essence of the invention is illustrated by illustrations, where figure 4 schematically shows the claimed device as a pump, with an illustration of its cross-section in figure 5, indicating the following positions:

1 - rotor with radial slots,

2 - stator,

3 - supporting discs,

4 - bracket with support roller,

5 - side covers (one is shown),

6, 6 '- inlet and outlet,

7 - sealing plate,

8 - piston plate.

The inventive rotor-plate device is universal in application, easy to manufacture and reliable in operation.

It should be appreciated that only those details are shown in the drawings that are necessary for understanding the essence of the proposal, and related equipment, well known to specialists in this field, are not shown in the drawings.

Unlike piston devices, this device does not have the most wearing part, the crankshaft, which increases reliability and increases the service life of the device.

In the claimed invention, used as a pump, compressor or hydro, pneumatic drive, silent vacuum cleaner, the number of working plates in the groove is at least two. A pressure ring is inserted into the seal ring groove. In the side covers, annular grooves are made at the level of the bottom of the rotor groove, serving to distribute the pressure that occurs under the plates.

The sub-plate space can be filled with a special sealing grease. For greater sealing, annular grooves are made in the side covers, between the lower and upper annular grooves, into which additional sealing rings are inserted, with a width equal to the width of the annular groove. The plates in the grooves in the upper part have a radial curvature equal to the width of the annular groove formed between the inner surface of the stator and the outer edge of the clamping ring.

In general, such a device can be characterized as a rotary-plate device for converting reciprocating motion into rotary motion, without a crank mechanism, used as a pump, compressor or hydro, pneumatic drive, silent vacuum cleaner, including a cylindrical stator with an inlet and an outlet, on the outer surface of which the brackets with support rollers move, side covers with annular grooves, the rotor, misaligned with respect to the stator to form chambers of unequal volume, with at least two radial grooves, and with at least two piston plates, installed in radial slots with the possibility of reciprocating movement, and the working piston plates have a length greater than the length of the rotor body, protruding from the slots of the rotor, and enter the radial slots of the supporting discs installed on both sides of the rotor so that the slots of the supporting discs coincided with the rotor slots, and working f the piston plates, leaving the rotor slots as much as possible, remained in the grooves of the supporting discs, while an additional seal was inserted into the radial grooves for tightness, and the annular grooves in the side covers serving to distribute the pressure arising under the plates are made at the level of the radial grooves located in the rotor.

Such a rotary vane device in the space between the piston plates and the radial grooves may additionally contain a sealing lubricant.

For additional sealing in the side covers of such a rotor-plate device, additional annular grooves with O-rings can be made.

The essence of the proposal is illustrated by drawings, where FIG. 5 schematically shows the device in longitudinal section, and FIG. 6 transverse, indicating the following positions:

1 - stator, 2 - rotor, 5 - side cover, 6, 6 '- inlet and outlet, 7 - sealing plate, 8 - piston plate, 9 - sealing ring, 10 - clamping ring, 11 - annular grooves.

The implementation of the claimed device is illustrated by an example:

When turning the rotor shaft, the volume enclosed between the plates (pistons) 8 begins to increase, and the medium being moved enters through the inlet 6 until the plate comes to the outlet 6 ', further turning the rotor shaft will lead to a decrease in the volume between the plates, and the transported medium will be forced out through the outlet 6 '. This process will be repeated with further rotation of the rotor shaft in one direction or the other.

At the same time, to increase the tightness between the chambers in each groove of the rotor, the number of plates 8 can be more than one.

In the claimed device used as pumps, compressors and silent vacuum cleaners, high sealing is ensured at low (up to 500 rpm) rotational speeds of the rotor shaft.

Claims (3)

1. A rotary vane device for converting reciprocating motion into rotational, used as either a pump, or a compressor, or a hydraulic drive, or a pneumatic drive, or a silent vacuum cleaner, including a cylindrical stator with an inlet and outlet, on the outer surface of which the staples move with support rollers, side covers with annular grooves, misaligned with respect to the stator to form chambers of unequal volume, a rotor with at least two radial grooves and with at least two piston plates mounted in radial grooves with the possibility of reciprocating movement and pivotally connected to the brackets with support rollers, and the working piston plates have a length greater than the length of the rotor body, protruding from the rotor slots, and enter the radial slots of the support discs installed on both sides from the rotor slots and enter the radial slots of the support discs installed on both sides of the rotor in such a way so that the grooves of the support discs coincide with the grooves of the rotor, and the working piston plates, leaving the grooves of the rotor as much as possible, remain in the grooves of the support discs, while an additional seal is inserted into the radial grooves for tightness, and the annular grooves in the side covers, which serve for the distribution of pressure arising under the plates are made at the level of radial grooves located in the rotor. 2. The rotary plate device according to claim 1, wherein the space between the piston plates and the radial grooves further comprises a sealing lubricant. 3. The rotary-plate device according to claim 1, in which additional annular grooves with sealing rings are made in the side covers.

Images