RU2203441C2 - Power-driven tool with safety clutch - Google Patents

Abstract

FIELD: mechanical engineering; power-driven tools with safety clutches. SUBSTANCE: tool has body, drive, spindle, and reduction unit that functions to impart rotary motion of drive to spindle. Safety clutch mounted on shaft in reduction unit circuit has driving and driven half- clutches. Driving half-clutch is made in the form of gear loosely mounted in radial direction on shaft and provided with hub. The latter has a number of radial holes to receive cam members enclosed by circular flat spring. Driven half-clutch is made in the form of bushing placed between shaft and hub coupled in radial direction with shaft and provided with a number of mating radial holes for engaging cam members. Limiting bushing is installed around flat spring with radial clearance relative to the latter. Gear has butt-end hole and flat spring is provided with side projection disposed in butt-end hole. EFFECT: enhanced stability of driving torque. 5 cl, 8 dwg

Description

 The invention relates to the field of mechanical engineering, in particular to a power tool containing a safety clutch, namely, drilling machines and perforators used in construction, exploration and drilling and blasting operations, in mechanical engineering, for the formation of holes in various structural and construction materials, as well as rocks.

 Power tools with a safety clutch are known, comprising a housing, a drive, a spindle, a gearbox that transfers the rotation of the drive to the spindle, and a safety clutch is installed on the shaft of the gearbox containing a drive coupling half, made in the form of a gear, freely mounted in the radial direction on the driven coupling half, and clutch disengagement occurs inside the gear housing. German patent 1965275, class F 16 D 7/06 of December 29, 69 - an analogue.

 Such a machine has the disadvantage of large diametrical dimensions of the safety clutch. This is due to the fact that the driven coupling half, located inside the gear case, contains radial holes for installing cylindrical compression springs and cam elements, balls, which, in turn, are recessed by a part of the spherical surface into the recesses on the inside of the gear ring gear . All marked coupling elements, due to their arrangement and radial arrangement, increase the dimensions of the coupling in the diametrical direction.

 The closest in technical essence is a power tool with a safety clutch, comprising a housing, a drive, a spindle, a gearbox that transfers the rotation of the drive to the spindle, and a safety clutch is installed on the shaft of the gearbox containing a drive coupling made in the form of a gear freely mounted in the radial direction on the shaft, and having a hub, and in the hub, a series of radial holes are made to accommodate cam elements covered by a flat annular spring, and a number of reciprocal holes are placed on the shaft deaf radial holes for engagement with cam members. German patent 3807308, cl. B 25 F 5/00 dated 03/05/88 - prototype.

 Despite the fact that this power tool lacks an analogue, it nevertheless has a disadvantage consisting in the instability of the moment transmitted by the coupling, as well as in increased weight and size parameters.

 The safety clutch of such a power tool has a number of blind radial holes in the design of the driven half-coupling on its shaft to accommodate cam elements in them. The depth tolerance of blind radial holes is wide enough, due to the peculiarities of the technological process of their formation, as a result of which the height of the part of the cam elements protruding above the cylindrical shaft surface has a certain scatter, which influences the magnitude of the transmission moment both for different couplings and for each clutch separately.

 In addition, in such a power tool, the driving coupling half is made in the form of a gear, which covers the driven coupling half, forming at the same time a cavity providing the possibility of uncoupling the coupling half. The deformation of a flat spring during the disengagement of the coupling halves occurs in the radial direction, in the cavity of the driving coupling half. Given the radial dimensions of the gear itself, the overall diametrical dimensions of the safety clutch in such a power tool, and therefore its mass, are increased.

 The basis of the invention is the task of creating a power tool with a safety clutch with a stable transmission torque.

 The problem is solved in that in a power tool with a safety clutch containing a housing, a drive, a spindle, a gearbox transmitting the rotation of the drive to the spindle, and a safety clutch is installed on the shaft of the gearbox containing the driving and driven half coupling, and the driving coupling half is made in the form of a gear freely installed in the radial direction on the shaft, and having a hub, and in the hub a number of radial holes are made to accommodate cam elements covered by a flat annular spring, driven floor the sleeve is formed as a sleeve located between the shaft and the hub, connected radially with the shaft and having a number of radial holes response for engagement with cam members.

 In the safety clutch of such a power tool, cam elements are located in the through radial holes of the sleeve, connected in the radial direction, for example by means of a press fit, with the shaft, and rely on the latter. The depth of the cam elements in the through radial holes is determined by the thickness of the walls of the sleeve, the diametrical dimensions of which are carried out using finishing operations, mainly grinding and, therefore, with great accuracy.

 The stability of the moment transmitted by the clutch depends on the stability of the height of the cam elements protruding above the sleeve. This height depends on the depth of the cam elements in the sleeve, and on the diametrical dimensions of the cam elements themselves.

 The use of balls or rollers as elements of rolling bearings as cam elements ensures high accuracy of their diametrical dimensions.

 The presence in the driven coupling half of the sleeve ensures the accuracy and stability of the depth of the cam elements.

 Taken together, it ensures the stability of the height of the part of the cam elements protruding above the sleeve, and hence the stability of the moment transmitted by the clutch.

 In addition, the arrangement of the gear and the coupling proper, which is consistent with respect to the shaft axis, makes it possible to reduce the diametrical dimensions of the safety coupling, and, consequently, the mass of the power tool as a whole.

 In addition, an end hole is made in the power tool with a safety clutch in the gear, and the flat spring has a lateral protrusion placed in the end hole.

 In such a power tool, cam elements are prevented from falling out from under the flat spring when it is displaced around the hub, especially during the operation of the clutch, since this displacement itself is limited. The end hole in the gear limits the displacement of the flat spring with its lateral protrusion both in the radial direction and in the direction of rotation around the hub. In this case, the gap between the ends of the flat spring, formed during the operation of the clutch, is always outside the area of the cam elements, which eliminates the loss of the latter from the radial holes of the hub and increases the reliability of the power tool as a whole.

 In addition, in a power tool with a safety clutch, a restriction sleeve is installed around a flat spring with a radial clearance relative to it.

 With a sharp increase in the moment of resistance on the clutch, the cam elements may unevenly act and, as a result, the plane spring displaces from the position of alignment with the shaft. In this case, it becomes possible for the cam elements to fall out of the holes of the hub. The presence of a restrictive sleeve that does not change its alignment with the shaft eliminates the offset from the alignment of the flat spring, keeping the cam elements from falling out of the holes of the gear hub. Such a power tool has increased reliability.

 In addition, in a power tool with a safety clutch, the restriction sleeve is mounted on the hub.

 In such a power tool, the restriction from the displacement of the flat spring from alignment with the hub occurs with the help of the restrictive sleeve mounted on the hub of the gear and rotating at the same time with the flat spring. When the clutch engages and the flat spring deforms between it and the restrictive sleeve, their mutual friction is absent, which eliminates wear and increases reliability.

 Along with this, in the power tool with a safety clutch, reciprocal cam elements are placed in reciprocal through radial holes of the sleeve, engaging cam elements located in the hub.

 In such a power tool, the engagement of the cam elements and reciprocal cam elements, if balls or rollers are used as such, occurs on cylindrical surfaces, and the clutch engages more smoothly, which is often necessary, especially in a heavy manual power tool with a large moment of resistance on the working tool, how it protects the operator from mechanical injury.

 A specific implementation of the invention is illustrated by the description and drawings.

 FIG. 1 is a longitudinal sectional view of a power tool with a safety clutch.

 FIG. 2 shows a safety clutch with additional cam elements in longitudinal section.

 FIG. 3 shows a safety clutch with additional cam elements in cross section.

 FIG. 4 is a cross-sectional view of a safety clutch at the moment of its operation when a lateral protrusion of a flat spring is placed in the end hole.

 Figure 5 depicts in longitudinal section an end hole with a lateral protrusion of a flat spring placed therein.

 FIG. 6 shows a safety clutch with a limiter sleeve mounted on a shaft in longitudinal section.

 FIG. 7 shows a safety clutch with a lateral protrusion of a flat spring in an end hole in a transverse section.

 FIG. 8 is a longitudinal sectional view of a safety clutch with a restriction sleeve mounted on a hub.

 A power tool with a safety clutch comprises a housing 1 (Fig. 1), a drive 2 located therein, a gear shaft 3 of which transmits the rotation of the drive 2 to the gear 4, which is the leading coupling half of the safety clutch 5, located on the shaft 6 of the gearbox 7. On the shaft 6 the drive gear 8 is located, transmitting the rotation of the shaft 6 to the drive gear 9 mounted on the spindle 10, on which a drill chuck 11 with a drill 12 is fixed. The gear 4 has a hub 13 in which a number of radial holes 14 are made to accommodate cam elements yarn 15 covered by a flat spring 16. Between the shaft 6 and the hub 13 is a driven coupling half, made in the form of a sleeve 17, connected with the shaft 6 in the radial direction by means of a press fit and having a number of through radial mating holes 18 in which the cam elements 15 are placed .

 The embodiment of the power tool provides for the presence in the gear 4 (Fig. 4) of the end hole 19, which houses the side protrusion 20 (Fig. 5) of a flat spring 16.

 In another embodiment, the power tool on the shaft 6 (Fig.6) is installed with a radial clearance relative to the flat spring 16 limiter sleeve 21 glass-shaped, the bottom 22 of which is fixed between the end of the sleeve 17 and the shoulder 23 of the shaft 6.

 In a further embodiment of the power tool, the restriction sleeve 21 is mounted and secured to the hub 13 (Fig. 8) using a spring washer 24.

 The embodiment of the power tool also provides for the presence of additional cam elements 25 (FIG. 2) placed in reciprocal through radial holes 18 of the sleeve 17 and meshed with cam elements 15 (FIG. 3) located in the radial holes 14 of the hub 13.

 A power tool with a safety clutch operates as follows. The rotation of the actuator 2 (Fig. 1) is transmitted to the gear 4, which is the leading coupling half of the safety clutch 5, with the help of the cam elements 15 of which the rotation is transmitted to the sleeve 17, which is the driven coupling half and mounted on the shaft 6 in the radial direction. The drive gear 8 mounted on the shaft 6 through the drive gear 9 transmits rotation to the spindle 10, on which the drill chuck 11 is fastened with the drill 12 clamped therein. Rotation of the drill 12 along with the operator’s supply force to the power tool leads to the formation of holes in the material being processed. In the case of jamming of the drill 12, which often happens, for example, when processing combined material with different hardness, the drill 12, and with it the spindle 10 with the shaft 6 and the sleeve 17, stop. At the same time, the drive 2 continues to rotate, simultaneously rotating the gear 4 with the hub 13, which with its load radially applied to the cam elements 15 extrudes the latter, overcoming the action of the flat spring 16 (Fig. 4), from the through radial mating holes 18 of the sleeve 17. The safety fuse is triggered clutch 5, which limits the moment transmitted to the hands of the operator holding the power tool.

 The magnitude of the moment transmitted by the safety clutch 5 depends both on the depth of the cam elements 15 (Fig. 7) in the reciprocal through radial holes 18 of the sleeve 17, and on the external diametrical dimensions of the cam elements themselves 15. The accuracy and stability of these two parameters ensures the accuracy and stability of the transmitted safety clutch 5 points. The use of 15 balls or rollers as cam elements, similar to those used, for example, in rolling bearings, ensures very high accuracy of their diametric dimensions. The presence of the sleeve 17 provides high accuracy of the depth of the cam elements 15, since this depth is determined by the wall thickness of the sleeve 17, the diametrical dimensions of which with the help of finishing operations, such as grinding, are performed with a high degree of accuracy. All this ultimately leads to great accuracy and stability of the transmitted moment as a single safety clutch 5, and all the safety clutch 5 of the same size.

 Positioning the safety clutch 5 (Fig. 1) along the axis of the shaft 6 in series with gear 4, the diametrical dimensions of the entire assembly are significantly reduced, since they are determined by only one of two parameters: either the outer diameter of the gear 4, or the outer diameter of the flat spring 16 at the moment of operation safety clutch 5 (figure 4). At the same time, the overall dimensions of the power tool are generally reduced.

 The operation of the safety clutch 5 is accompanied by the release of the cam elements from the mating through radial holes 18 and the deformation of the flat spring 16, the ends of which diverge, forming a space through which the cam elements 15 can fall out of the radial holes 14 of the hub 13. To eliminate this, the gear 4 is made the end hole 19, and the flat spring 16 has a lateral protrusion 20 (figure 5), placed in the end hole 19. With this embodiment of the power tool excluded the rotation of the flat spring 16 relates flax hub 13, and with it excluded from entering the radial holes 14 of the hub 13 into the space between the ends of the leaf spring 16 (Figure 4) and thus eliminating the space loss across the jaw members 15.

 The implementation of the radial holes 14 in the hub 13 and the reciprocal through radial holes 18 in the sleeve 17 is carried out with certain tolerances, which determines some scatter from their geometric position. As a result of this, when the safety clutch 5 is activated, the cam elements 15 exit from the mating through radial holes 18 of the sleeve 17 not at the same time, which causes the spring of the flat spring 16 to be uneven in diametrical expression with the formation of a one-sided gap between the hub 13 and the flat spring 16. Through this gap, it may fall out cam elements 15 from the radial holes 14 of the hub 13. To exclude such a loss on the shaft 6 (Fig.6) installed limit sleeve 21 with a radial clearance include just a flat spring 16. The restrictive sleeve 21 has a cup-shaped shape, the bottom 22 of which is sandwiched between the shoulder 23 of the shaft 6 and the end face of the sleeve 17, and limits the diametrical deformation of the flat spring 16, excluding the loss of the cam elements 15 from the radial holes 14 of the hub 13, but at the same time time does not interfere with the operation of the safety clutch 5. This embodiment of the power tool increases its reliability.

 In order to achieve even greater reliability of the power tool, the restriction sleeve 21 (Fig. 8) is fixed to the hub 13. When the safety clutch 5 is activated and the flat spring 16 is deformed, the latter can touch the restrictive sleeve 21. In this case, the rotational movement of the flat spring 16 fixed around the hub 13, occurs together with the restrictive sleeve 21, also mounted on the hub 13, which eliminates sliding friction between them, and therefore their wear.

 In the case where a softer response of the safety clutch 5 is required, especially in a power tool of high power and with a significant moment of resistance on the drill 12, reciprocal cam elements 25 are placed in the reciprocal through radial holes 18 of the sleeve 17 (Fig. 2), engaged with the cam elements 15 (FIG. 3). When the safety clutch 5 is activated, the rolling of the cam elements 15 relative to the counter cam elements 25, if they are made in the form of balls or rollers, occurs on a cylindrical surface, and the transfer moment of the safety clutch 5 increases more smoothly. This significantly reduces the possibility of injury to the operator holding the power tool.

Claims (5)

 1. A power tool with a safety clutch, comprising a housing, a drive, a spindle, a gearbox that transfers the rotation of the drive to the spindle, and a safety clutch is installed on the shaft of the gearbox containing a drive and driven coupling halves, and the drive coupling half is made in the form of a gear freely mounted in a radial direction on the shaft and having a hub, and in the hub a number of radial holes are made to accommodate cam elements covered by an annular flat spring, characterized in that the driven coupling half is made in in the form of a sleeve located between the shaft and the hub, connected in a radial direction with the shaft and having a number of mating through radial holes for engagement with the cam elements.  2. A power tool with a safety clutch according to claim 1, characterized in that the end hole is made in the gear, and the flat spring has a lateral protrusion located in the end hole.  3. A power tool with a safety clutch according to claim 1 or 2, characterized in that a restriction sleeve is installed around a flat spring with a radial clearance relative to it.  4. A power tool with a safety clutch according to any one of claims 1 to 3, characterized in that the limit sleeve is mounted on the hub.  5. A power tool with a safety clutch according to any one of claims 1 to 4, characterized in that in the through through radial holes of the sleeve there are mating cam elements engaged with cam elements located in the hub.

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