EA014977B1 - Power-driven torque intensifier - Google Patents

Abstract

A torque intensifying tool for tightening and loosening threaded connectors, such as nut, which increases torque, comprising at least one torque intensifier means having a torque intensifier housing portion, having a turning input means and a first output means for turning a threaded connector and a second output means reacts to an object being next to said threaded connector; a drive operatively connected with said input means for transmitting a torque from said drive through said intensifying means to a threaded connector, so that said torque intensifier housing portion together with said second output means are adapted to: in the first mode of operation connect to the first output means having the speed and first torque of threaded connector, providing rotation of the intensifier housing portion together with the second output means and the first output means in the same direction and in the second mode of operation disconnect to the first output means having second speed and second torque of threaded connector at a lower than first speed but higher torque than said input means, providing rotation of the intensifier housing portion together with second output means in one direction and first output means in the opposite direction with equal turning force; wherein first output means is adapted to turn in both modes, while the second output means is adapted to turn in the first mode reacting to an object being next to said threaded connector, in the second mode. Such tool design provides to minimize a number of bearing supports for its turning parts resulting in lesser weight and dimensions of a manual tool with high-speed drive.

Description

The present invention relates to a tool that increases torque.

In threaded connectors, when the nut comes in or is in contact with the bearing surface, its speed with a tool for tightening or loosening is very small. However, the user wants the rotation speed to be high, so that the nut can be twisted or twisted very quickly.

Conventional impact wrenches, which provide a high speed of twisting or twisting, have the disadvantage that they do not work very precisely and very slowly when the nut contacts the bearing surface. Mechanized tools for tightening or loosening parts of threaded connectors work more precisely, but relatively slowly, when tightening or twisting. However, they act more quickly than percussion pistols when the nut is already in contact with the bearing surface. Power tools typically have a pneumatic, electric, or hydraulic motor. It rotates gears that reduce speed, but increase the relatively low output torque of the engine. The higher the torque, the greater the gear ratio and, obviously, the lower the speed of rotation of the nut. Therefore, there are usually two speed adjusting mechanisms; one for tightening or twisting, and the other for final or initial higher torque (KH 2154709).

It is known that when twisting the nut, usually a lower torque is required than when twisting, which is due to the possible breaking of the thread when loosening the nut. This means that the torque created by the pneumatic motor used for small pneumatic wrenches can be increased by using a small multiplier to increase the motor torque without significantly reducing the speed of twisting and twisting. For most handheld mechanized tools, in which the motor case is not connected to the drive body, it is especially important that the engine torque does not exceed the hand resistance, or the tool body of the tool cannot be held and it will begin to rotate in the hand.

There are many mechanical torque multipliers on the market, and some of them have two speed mechanisms, some react to the tip of the bolt, others to the opposing handle. Common to all is that regardless of the applied torque or speed, the drive housing rotates in the opposite direction relative to the output shaft. None of them gives such a speed of twisting or twisting, in which the entire body of the drive together with the internal drive assembly and output drive rotate at the same high speed in one direction.

Portable mechanized tools are also available on the market, such as those disclosed in ϋδ 2569244, where pressing the tool on the threaded connector increases or decreases the air supply and, consequently, the output torque. However, there are no tools on the market where, depending on the pressure on the threaded connector, the rotation of the drive housing, its gears and the output shaft in the same direction and at the same speed can change to apply a rotational force on the gears and the output shaft in the same direction and at the same time the oppositely directed rotational force on the drive housing. Portable, mechanized tools are also available on the market where the engine torque can be reduced to increase the engine speed and, consequently, the speed of the tool.

In addition, the two-speed mechanism of mechanical torque multipliers usually operates on the principle of disconnecting one or several planetary gear stages and the remaining steps (CI 2154709). This reduces the gear ratio to a higher speed and lower torque, and therefore, as soon as the nut stops, all the stages of the planetary gear set will become functional with more torque at a lower speed. However, the body still tends to counteract in the direction opposite to the direction of rotation of the gears at low and high gear ratios. In other words, when the drive and gears are subjected to a rotating force in one direction, the housing is exposed to the same rotating force in the opposite direction. The problem is that at high speeds, the gears and the output shaft rotate so fast in the drive case that bearings are needed for almost all rotating parts, which makes the tool heavier and increases its size.

Brief description of the invention

Accordingly, the object of this invention is to provide a tool that increases the torque in which the above-mentioned disadvantages of the known devices are eliminated.

The tool that increases torque, in accordance with this invention, is based on the idea of abandoning the usual same, simultaneous, but opposite rotational action and counteraction, when a high nut rotation speed is required to eliminate the need to use almost all rotating parts of bearings.

In accordance with the aforementioned objects of the invention and others, which will become apparent from the following description, one of the objects of the present invention is in the summary of the invention.

- 1 014977 A rule for tightening or loosening a threaded connector part, such as a nut, which increases the torque, including at least one torque multiplier having a housing, rotating input means, first output means for rotating the threaded connector part, and second output means for countering an object adjacent to the specified part of the threaded connector; an actuator which during operation is connected to an input means for transmitting torque from the actuator to the input means and then through a multiplier to a threaded connector part, wherein the multiplier body together with the second output means is adapted to connect with the first output means in the first operation mode, whereby the first speed and the first torque of rotation of the threaded connector part take place, ensuring rotation of the multiplier body together with the second output means the first output means in one direction and disconnection with the first output means in the second mode of operation, in which the second speed and the second torque of rotation of the threaded connector part occur, which are respectively lower than the first speed and greater than the first torque, ensuring rotation of the multiplier body together with second output means in one direction and first output means in the opposite direction with an equal rotational force, the first output means being provided with the ability to rotate in both modes, while the second output means - with the ability to rotate in the first mode and to counteract an object located next to the threaded connector part in the second mode.

In order for this tool according to the invention of the housing, the gears of the torque multiplier and the input / output means to rotate in the same direction at the same speed, the usual rotation of the parts in the same and opposite direction should be temporarily blocked. This can be done in many ways. For example, you can lock the gears so that they cannot rotate freely in the housing, or block the planetary gear, so that the sun wheel cannot rotate it, or lock the housing and the output shaft, so that they cannot rotate independently of each other, or block acting actuator and opposing actuator or their connection, or block one part of the threaded connector of the other, if both are to be screwed together and then rotated independently of each other, etc.

Achieving the same result without joint rotation of the casing, gears and the output shaft and the input shaft would be too difficult due to the fact that it was necessary to temporarily disable all or at least all but one of the cage gears, whereas in accordance with this the invention temporarily shuts off the whole body of the multiplier by simply locking two usually oppositely rotating parts.

In the case of a tool according to the present invention, during rotation of a threaded connector part, such as a nut, and application of an acting force, the counter force can be compensated by applying a counteraction: to an adjacent object, such as a neighboring nut, to another part of the threaded connector, for example a washer, to another one part of a threaded connector, such as a sleeve, etc.

New distinctive features, which are considered as characteristic of the present invention, are set forth, in particular, in the attached claims. However, the invention itself, both in terms of its design and method of operation, together with its additional objectives and advantages, will become more clear from the following description of specific embodiments together with the attached figures.

Brief description of the figures

FIG. 1a and 1b depict a tool for tightening or loosening a part of a threaded connector that increases torque in accordance with one embodiment of the present invention, where FIG. 1a corresponds to the first mode of operation of the tool, and FIG. 1b corresponds to the second mode of operation of the instrument;

in fig. 2a-2c depict a tool that increases torque, in accordance with another embodiment of the present invention, where FIG. 2a corresponds to the first mode of operation of the tool, FIG. 2b corresponds to the second mode of operation of the tool, and FIG. 2c shows the end of the tool;

in fig. 3 shows a tool for tightening or loosening a threaded connector part that increases torque, in accordance with a further embodiment of the present invention, and FIG. 4a and 4b depict another embodiment of this tool that increases torque, with two different modes of operation.

Description of preferred embodiments

A tool for tightening or loosening a threaded connector part that increases the torque comprises a drive means that is generally identified by the position 1. The drive means 1 can have a drive body 2 and a drive that is identified by the position 3. When

- 2 014977 water tool 1 may be mechanically driven, in which case it may include an engine. Also, the drive means 1 may be a manual drive, for example a wrench with an adjustable torque. The drive means 1 produces a torque that is transmitted for the work. In the embodiment shown in FIG. 1a, 1b, the actuator housing 2 has a handle 4 that must be held by the operator, and is provided with switching means 5 for switching the drive means from the inoperative position to the operating position.

The tool that increases the torque according to this invention also contains at least one torque multiplier, which is generally identified by the position 6. The torque multiplier 6 has a multiplier body 7 and transmission means connected to the drive means 1. In an embodiment shown in FIG. 1a, 1b, the transmission means include a sun wheel 8 having a shaft which forms the input means, a planetary gear 9 and a planetary casing 10. The multiplier body 7 is equipped with an internal gear gear 11, which runs only along the longitudinal part of the body 7.

The tool that increases the torque in accordance with this invention also comprises a driving member for rotating the part of the threaded connector, which is generally identified by the position 12 and forms the first output means. Leading element 12 has a leading part 13, which can be made, for example, in the form of a square shank and a rear part 14, which is connected to a torque multiplier with the possibility of transmitting driving force, for example, by means of a key connection. The connection of the drive means 1 with the multiplier 6 and the driving element 12 ensures the transmission of torque from the driving means to the driving member. The torque multiplier 6 can be configured to provide any desired increase in torque produced by the driving means 1.

The tool, which increases the torque, also contains a counteracting element to counteract during rotation of the part of the threaded connector to an object adjacent to it, which is identified by the position 15 and forms the second output means. The opposing element 15 is provided with a means 16 for connecting with an element opposing a stationary object, for example, an opposing lever, for example, using dowels. The opposing element 15 is rigidly connected to the housing 7 of the torque multiplier. In the embodiment shown in FIG. 1 and 1b, the opposing element 15 is made in one piece with the torque multiplier housing.

The tool that increases torque has two different modes of operation.

In the first mode of operation, when the torque is transmitted from the drive means 1 through the torque multiplier to the driving element 12, the first (lower) torque and the first (higher) rotational speed occur. This is advantageous when it is necessary to screw one part of a threaded connector, for example a nut, onto another part of a threaded connector, for example a bolt, at high speed until the nut comes into contact with the washer or the supporting surface. In this mode of operation, the torque is transmitted from the drive through the multiplier case 7, the torque multiplier gears, the second output means or the counter element 15 and the first output means or the driving member 12, so that the multiplier body 7 together with the first output means and the second output means rotate in one direction and with torque and speed equal to the moment and speed of the input means.

In the second mode of operation, the torque is transmitted from the drive means 1 through a torque multiplier to the driving element 12, so that the torque multiplier body 7 together with the second output means or the counter element 15 are subjected to a rotating force in one direction, while the first output means or the driving element 12 is subjected to the action of an equal rotating force in the opposite direction at the second speed and the second torque, which are respectively less than the first orosti and greater than the first torque and the speed, respectively, and torque input means.

To switch the tool from one operating mode to another in the embodiment shown in FIG. 1a, 1b, for example, pushers 17 in the form of pins or the like are provided. When the nut comes in contact with the washer, the pushers 17, which are illustrating the first mode of operation of FIG. 1a are pushed out of the housing of the torque multiplier 7, moving in the axial direction opposite to the threaded connector, as shown in FIG. 1b, and the planetary casing 10, which has been engaged with the internal gear gear 11 of the multiplier housing 7, disengages from the above gear wheel, so that the first output means or the driving element 12 and the second output means or the opposing element 15 can rotate in opposite directions . To switch the torque boosting tool from one operating mode to another, any other acceptable means can be used.

According to the present invention, in an instrument that increases torque, the torque multiplier body 7 and the drive body 2 are functionally connected to each other. In particular, the housing 7 of the torque multiplier can rotate relative to the housing 2 of the drive. For this purpose, as shown in FIG. 1a, 1b, a part of the drive housing 2, which may contain additional means for increasing the torque (the main drive), can be pushed into the torque multiplier housing 7 and lean on the bearing 18 therein. With this design, the torque multiplication housing 7 can rotate freely relative to the housing 2 of the drive. The housing 2 of the drive can be made in the form of a shell, support, frame, etc. to drive. This can also be done by automatic switching when the required torque exceeds a predetermined force. I

In another embodiment of the present invention, which is shown in FIG. 2a-2c, the first output means is in the form of a drive sleeve 21, which has a part 22 with a polygonal inner surface for engagement with the nut and a part 23 with a polygonal outer surface. The second output means is also made in the form of an anti-clutch, which has a part 24 with a polygonal surface for coupling with an adjacent object, such as a washer, and a part 25 with an internal polygonal hole having a configuration that provides interaction with the polygonal part 23 of the driving clutch. The drive coupling has a receiving opening 26, which may include a square shank 27 of the tool. The key portion 28 of this tool is inserted into the internal key adapter 29, which is rigidly connected to the counter coupling.

The drive clutch is mounted for movement in the axial direction relative to the opposing clutch. For the first mode of operation, the part 23 of the drive clutch engages with the part 25 of the opposing clutch, so that the clutches are fixedly connected one to the other as shown in FIG. 2a, and the torque of the drive means 1 is transmitted through a torque multiplier to the drive clutch with a speed and a torque equal to the speed and torque of the input means. In this mode of operation, the first and second output means rotate.

When, as shown in FIG. 2b, the drive clutch moves in the axial direction, for example, so that its part 23 disengages from the workpiece 25 of the opposing clutch, the drive clutch and the counteracting clutch are no longer connected one to the other in the second operating mode, and they rotate in opposite directions when same torque and lower speed, but more torque, compared with the input means. In this mode, the first output means or the leading clutch rotates, while the second output means or the opposing clutch counteracts.

In this embodiment, in the first mode of operation, the torque multiplier housing, together with the drive clutch and the opposing clutch, rotate in one direction at a speed and torque equal to the speed and torque of the input means, while in the second mode of operation, the torque multiplier housing together with the counteract clutch subjected to the action of the rotating force in one direction, while the drive clutch is exposed to the action of the rotating force in the opposite direction.

It should be borne in mind that in the second mode of operation, the first and second outputs can act both as leading means or opposing means in opposite directions, depending on the application.

In the embodiment shown in FIG. 3, the nut to be twisted or loosened is identified by the position 31, the bolt to which the nut is to be screwed or to be twisted is identified by the position 32, and the washer is identified by the position 33 and has a radially outer retaining part 34, and radially inner part 35, which can engage with the bolt 32. Means are provided for transmitting torque in the above two modes of operation. They can be, for example, connecting studs 36, which are included in respectively located holes 38 nuts and washers.

In the first mode of operation, the studs 36 interconnect a nut and a washer, so that they rotate together with a speed and a torque equal to the speed and torque of the input means. When the nut comes in contact with the washer and the torque increases, the studs 36 collapse, for example, are cut off, so that the nut rotates with greater torque and at lower speed than the input means, while the washer creates a counteraction.

It should be borne in mind that at least the two modes described here are merely examples. Other modes can be added to the modes considered here, and / or the above input means and / or output means.

Although the tool that increases the torque described above is a two-speed tool, this invention is not limited to just two speeds, but may have multiple speeds, as shown, for example, in FIG. 4a, 4b. For example, a drive connected to the input means of a torque multiplier may further include an intermediate drive, so that the drive includes, for example, the main drive housing and the intermediate drive housing 50.

In this case, the tool can perform work at least at three speeds, and at the first speed and the first torque in the specified first mode of operation, the specified part of the intermediate drive housing is rotatably connected with at least one

- 4 014977 with one part of the main drive housing and without rotation with the multiplier case, at the second speed and second torque, which are respectively lower than the first speed and greater than the first torque in the specified first mode of operation, the specified part of the intermediate drive housing is connected without rotation at least one part of the main drive housing and rotatably with the multiplier case, and at the third speed and the third torque, which are respectively less than the second speed greater than the second torque in said second mode of operation, said intermediate drive housing portion is connected without rotation with said at least one portion of the main drive housing and the housing of the multiplier.

When two usually rotating in opposite directions parts are temporarily interconnected in the torque multiplier or at the end of it, the intermediate drive housing 50, which contains at least one multiplier block, such as a planetary gear stage, for example, is connected to the housing torque multiplier so that it does not rotate relative to it, the rotation of the torque multiplier body together with the first and second output means occurs with speed and torque ohm derived from the housing 2 of the drive. When the torque required to rotate the threaded connector part exceeds the torque from the drive housing 2, and the intermediate drive housing 50 is fixedly connected to the drive housing 2, and connected to rotate to the torque multiplier housing, the rotation of the torque multiplier housing 7 the first and second output means occurs at a lower speed, but more torque, received from the drive housing 2. When the friction of rotation of a threaded connector is such that a tool is switched from one operating mode to another, the torque applied to the threaded connector part increases many times, while the rotational speed drops further. FIG. 4a, an intermediate drive housing 50 is fixedly connected to the multiplier housing 7, whereas in FIG. 4b, the intermediate actuator housing 50 is fixedly connected to the actuator housing 2.

It should be borne in mind that each of the elements described above, or two, or several together, may also find useful applications in other types of structures that differ from the types described above.

Although this invention is illustrated and described as embodiments of a mechanical torque multiplier, it is not intended to be limited to the details, since various modifications and design variations can be developed without any departure from the essence of the present invention.

The preceding description so fully reveals the essence of the present invention that specialists without any additional analysis using modern knowledge easily adapt it to various uses, without losing the distinctive features that, from the point of view of the previous level of technology in the industry, rightly constitute the essential features of general or specific aspects of the present invention.

New claimed materials that are supposed to be protected by a patent are set forth in the appended claims.

Claims (16)

CLAIM 1. A tool for tightening or loosening a threaded connector part, such as a nut that increases torque, including at least one torque multiplier having a housing, a rotatable input means, first output means for rotating the threaded connector parts, and second output means for providing counteraction to an object adjacent to the specified part of the threaded connector; a drive, which during operation is connected to the input means for transmitting torque from the drive to the input means and then through the multiplier to the part of the threaded connector, while the multiplier housing together with the second output means are configured to connect to the first output means in the first mode of operation, at which there is a first speed and a first torque of rotation of the threaded connector part, ensuring rotation of the multiplier housing together with the second output means the first output means in one direction and disconnects with the first output means in the second mode of operation, in which there is a second speed and a second torque of rotation of the threaded connector parts, which are respectively less than the first speed and more than the first torque, with the multiplier housing rotating together the second output means in one direction and the first output means in the opposite direction with equal rotational force, and the first output means is made with the ability to rotate in both modes, while the second output means with the ability to rotate in the first mode and to oppose an object located next to the threaded connector part in the second mode. - 5 014977 2. The tool according to claim 1, characterized in that the first output means is a leading element for rotating a threaded connector part, while the second output means is a counteracting element for counteracting an adjacent object during rotation of this part. 3. The tool according to claim 1, characterized in that the first output means is a driving clutch for rotating a part of a threaded connector, while the second output means is a counteracting clutch to counteract an object adjacent to it during rotation of this part. 4. The tool according to claim 1, characterized in that it further includes a main drive, at least one part of which is functionally connected to the multiplier housing, so that the multiplier housing can rotate relative to the specified part of the main drive housing. 5. The tool according to claim 4, characterized in that it further includes an intermediate drive designed to perform work at least three speeds, and at the first speed and first torque in the specified first mode of operation, the specified part of the housing of the intermediate drive is connected with the possibility rotation with the specified at least one part of the main drive housing and without rotation with the multiplier housing, at the second speed and second torque, which are respectively less than the first speed and above the first torque in the specified first mode of operation, the specified part of the housing of the intermediate drive is connected without rotation with the specified at least one part of the housing of the main drive and can rotate with the housing of the multiplier, and at the third speed and third torque, which are respectively less than the second speed and more than the second torque in the specified second mode of operation, the specified part of the housing of the intermediate drive is connected without rotation with the specified at least one part of the housing the main drive and the housing of the multiplier. 6. The tool according to claim 2, characterized in that the multiplier housing is made in one piece with the opposing element. 7. The tool according to claim 2, characterized in that the housing of the multiplier is made with the possibility of connection with the opposing element through the part of the threaded connector. 8. The tool according to claim 1, characterized in that it is designed to connect one part of the threaded connector to another part of the threaded connector into a single unit in the first mode of operation and to disconnect the parts of the threaded connector in the second mode of operation. 9. The tool according to claim 1, characterized in that it further includes a switch for automatically switching the tool from the first operating mode to the second operating mode in a position where one part of the threaded connector comes into contact with another part of the threaded connector. 10. The tool according to claim 1, characterized in that it further includes a switch for switching the tool by the operator from the first mode of operation to the second mode of operation, when one part of the threaded connector comes into contact with another part of the threaded connector. 11. The tool according to claim 1, characterized in that it further includes a switch for switching the tool from the first operating mode to the second operating mode by moving the tool in a direction axial to the threaded connector in a state where one part of the threaded connector comes into contact with another threaded connector part. 12. The tool according to claim 4, characterized in that the main drive is made in the form of a manual wrench. 13. The tool according to claim 4, characterized in that the main drive includes an engine. 14. The tool according to item 13, wherein the main drive includes at least one additional multiplier to increase the output torque of the main drive. 15. The tool according to 14, characterized in that at least one of these multipliers is configured to limit the output torque of the drive and thereby provide the operator with the ability to absorb the forces of the specified reaction. 16. The tool according to claim 1, characterized in that the drive includes a mechanical wrench.