RU2639589C2 - Method of installing part and device for its implementation (versions) - Google Patents

Abstract

FIELD: technological processes.SUBSTANCE: part is placed with orientation on the plane and, at least, with one hole providing initial guaranteed radial clearances between the base surfaces of the part holes and internal expanding installation elements of the installation devices, which includes a collet of the expanding installation element with a slotted spring. By setting the ratio of the axial and radial rigidity the collet to be greater than or equal to one, the part installation process sequence is set as its pre-basing, pre-fixing, sending of the part towards the installation plane, final basing and final fixing of the part.EFFECT: accuracy and reliability of the part installation during the implementation of technological operations.3 cl, 9 dwg

Description

The group of inventions relates to mechanical engineering, in particular to machining, assembly and control, and can be used to install and fix parts along the plane and holes to increase the accuracy and reliability of the installation of parts along the plane and holes, as well as to increase the accessibility zone of the part surfaces for supply and operation of the working tool during machining, assembly or control.

The prior art method for installing parts on a plane and holes with axes intersecting it, implemented using a device for mounting parts (SU No. 639681, B23Q 3/00, publ. 12/30/1978). Collet pins made in the form of a split sleeve with an expandable housing associated with the drive are housed in the device body. The supporting end face of the split sleeve is made in the form of a spherical shaft, spring-loaded in the direction of the housing, which allows for self-installation of the split sleeve and increases the accuracy of the installation of the part. First, the part is placed so that the collet fingers are inside its mounting holes with an initial guaranteed clearance. Then, using the hydraulic drive, the collet fingers are expanded, thereby securing the workpiece.

The disadvantage of this method and the device that implements it is the lack of retanning of the fixed part in the direction of the installation base. As a result of this, discontinuity of the contact along the installation base is possible and the part is skewed, which negatively affects the accuracy of the installation. To eliminate this drawback, in practice, additional clamping elements are used - hooks. However, this limits the access area of the working tool to the surfaces of the part.

A known method of installing parts of the type flange on the end plane and the hole, implemented using a mandrel J-290 firm TOBLER (France). The J-290 mandrel includes sliding rusks and a sliding sleeve. The centering of the installed part and the clamp to the fixed stop is carried out using traction. The part is first placed on the mandrel, orienting along the hole and the end plane, providing initial guaranteed radial clearances between the crackers and the base surface of the part’s hole. After that, the part is based, eliminating radial gaps by expanding the mounting elements - crackers. Then the part is fixed, by making a force short circuit between the installation elements and the base surface of the hole of the part. After this, the part is blanched in the direction of the end plane due to compression of the additionally introduced elements - springs located between the movable and fixed elements of the device.

The disadvantage of this method and the device that implements it is the difficulty of using a mandrel for installation on a plane and holes with axes intersecting its body parts such as flanges with holes having a figured profile, as they can be damaged and, consequently, reduce the quality and reliability of the installation. In addition, due to the significant size and structural complexity of the mandrel, it is difficult to use the device to install parts through holes of small diameter. The presence of movable joints between the elements of the mandrel leads to wear of their mating surfaces, an increase in the gaps, a decrease in the service life and a decrease in the accuracy of the installation of the part.

There is also a method of installing parts, implemented using a clamping device, in which the part is first placed in the device, orienting along the plane and the holes with axes intersecting it and providing initial guaranteed radial clearances between the internal expanding mounting elements in the form of collet extension fingers and the base surfaces of the part holes , then the part is based, eliminating radial clearances by expanding the collet retracting fingers and fix the part, carrying out a power closure e therebetween and base surfaces of the holes items, then the items carried chambering in the direction of the mounting plane by resilient axial deformation of the compression collet fingers shall be sent (see. EP 0925871, B23Q 3/06, publ. 22.12.2004).

The disadvantages of this method and the clamping device that implements it are the low accuracy of the base in it due to the negative influence of uncompensated gaps between the holes and the mounting elements, as well as the structural complexity of the device, which reduces the reliability and service life of it.

Closest to the claimed group of inventions in terms of technical nature and the technical result achieved by using it is a method of installing a part along a plane and holes, including placing the part in a fixture with orientation along the plane and holes with axes intersecting it and providing initial guaranteed radial clearances between internal expansion installation elements in the form of collet fingers and the base surfaces of the holes of the part, the base of the part with the elimination m of radial clearances by expanding the collet fingers and securing the part by means of a force closure between them and the base surfaces of the holes of the part, sending the part in the direction of the mounting plane by elastic axial compression deformation of the compression collet fingers, offering first a choice and assessment of the design and geometric parameters of the base holes of the part and the corresponding shape of the working surfaces of the collet fingers, the determination of the required clamping force and the sequence I installation steps, and then the obtained results reference axial and radial stiffness of collet fingers shall be sent, the ratio of which is set sequence and parameters of the installation process one or greater (see. RF patent No. 2201332, IPC B23Q 3/06, publ. 03/27/2003).

The disadvantage of this method and the device that implements it is the low rigidity of the collet extending finger, which arises due to the fact that the monolithic collet has axial and radial slots, forming a non-rigid slotted spring in the back of the collet, as well as the presence of uncompensated radial gaps between the collet and the rod, which entails the appearance errors in the installation of the part and the instability of its position in the device.

The problem to which the present group of inventions is directed is to increase the accuracy, efficiency, stability and reliability of the method of installing parts along the plane and holes.

The technical result achieved is to increase the accuracy of basing, the reliability of the fastening and the efficiency of installation of the part along the plane and holes.

The task underlying this group of inventions with the achievement of the claimed technical result is solved by the fact that in the method of installing the part, including placing the part in the device with orientation along the plane and at least one hole with its axis intersecting and providing initial guaranteed radial clearances between the internal expandable mounting elements and the base surfaces of the part openings, the base of the part with the elimination of radial gaps by expanding the radial petals gy of expanding mounting elements and securing the part by means of a power closure between them and the base surfaces of the part openings, sending the part in the direction of the mounting plane due to elastic compression deformation of the axial lobes of the collet of the expanding mounting elements, evaluating the design and geometric parameters of the base holes of the part and choosing the corresponding forms of working surfaces of expandable mounting elements, determining the required clamping forces, setting the parameters of the installation process and the sequence If the steps of the installation process are carried out by the ratio of the axial and radial stiffness of the grips of the expanding installation elements to a value greater than or equal to unity, the radial clearances between the inner surface of the collet hole and the rod-rod of the expanding installation element, and also between the internal surface of the part and the outer surface of the slotted spring made in the middle part of the collet housing of the expanding installation element, then, according to the results obtained, design parameters are assigned slotted spring based on its deformation ability, then change collet slotted spring petals axial position uniformly and equilateral eliminate all radial clearances and perform forceful closure of the technological subsystem "detail-device".

The task underlying this group of inventions with the achievement of the claimed technical result is also solved by the fact that in the device for implementing the inventive method for installing parts according to the first embodiment, including a base in which at least one expandable installation element is installed, oriented along the installation plane and made in the form of a collet extending finger containing a collet and a rod-rod, mating on reciprocal working conical surfaces, the middle part of the collet body supporting bead and the radial lobes of the collet is designed as a slotted spring adapted to uniform sampling and equilateral radial gaps dosylka components and power circuit technology subsystem "item-device".

The task underlying this group of inventions with the achievement of the claimed technical result is also solved by the fact that the device for implementing the inventive method for installing parts according to the second embodiment, including a base in which at least one expandable installation element is installed, oriented along the installation plane and made in the form of a collet extending finger containing a collet and a rod-rod, mating on reciprocal working conical surfaces, is provided with a rigidly fixed at the base of the guide sleeve with a supporting collar with the possibility of contact with the installation plane of the latter, the middle part of the collet body is made in the form of a slotted spring located in the inner cavity of the guide sleeve, made with the possibility of uniform and equilateral selection of radial clearances, sending the part and power circuit of the technological subsystem "detail -device".

In addition, the slotted spring is made in the form of staggered alternating axial stepwise symmetrical slots, forming axial petals of the collet in the form of leaf springs with seals in the zone of the bridge of the slots and forming the axial spring part of the collet.

Preliminary setting of the radial clearance values between the inner surface of the collet hole and the rod-rod of the expanding mounting element, as well as between the inner surface of the part and the outer surface of the slotted spring, makes it possible to determine and assign reasonable values of the total clearance and allowable values of deviations in the sizes of the corresponding hole diameters (central collet hole, based hole parts and / or central holes of the guide sleeve) and the corresponding shaft diameters (w current-traction, outer diameter of the collet), which, along with the fittings in their mates, are selected based on the deformation capabilities of the slotted spring, it is guaranteed to eliminate working radial clearances by compensation and thereby eliminate their negative (negative) effect on the centering and basing accuracy on a hidden base - axis of the hole parts.

The designational rational constructional parameters of the slotted spring, made in the middle of the collet body of the expanding mounting element, based on its deformation ability and strength, enable its cantilever fragments to be stably elastically deformed as beam arrows with ends clamped in the zones of the jumpers of the slots and by skewing the position axial petals of the collet within the values of the axial slots to uniformly and equilaterally eliminate the working radial clearances.

The presence of significant features distinctive from the prototype allows us to recognize the claimed technical solutions as new.

A comparative analysis of the proposed technical solutions with identified analogues of the prior art, from which the group of inventions does not explicitly follow for a tooling specialist, showed that it is unknown and the influence of its distinctive features on the technical result indicated by the applicant is not confirmed, therefore, the claimed group of inventions meets the condition of "inventive step", and taking into account the possibility of industrial production of devices for installing parts with orient Using surface and hole mounting, we can conclude that it meets the patentability criteria.

A preferred embodiment of the proposed technical solution is described below based on the drawings, where

- in FIG. 1 shows a general view of the proposed method for installing the part along the plane and the openings of the devices of the mounting elements of the devices in the form of collet extending fingers in an axial section, when using the device for long holes of the part;

- in FIG. 2 - the same for short holes of the part;

- in FIG. 3 shows a top view of the mounting element of the device without an installed part;

- in FIG. 4 shows an axial section of the mounting element of the device along the plane BB;

- in FIG. 5 - the same, on the plane BB;

- in FIG. 6 and 7 are enlarged figures highlighted in FIG. 1 and 2 of zone A of the slotted spring (lower in Fig. 1) of the collet of the extender finger in a radial section in the initial (Fig. 6 - without deformation) and in the working (Fig. 7 - during deformation) states;

- in FIG. 8 is a sampling diagram (compensation, exclusion, elimination) of working radial gaps between a collet, a rod-rod and holes;

- in FIG. 9 shows a layout of tolerances forming gaps.

In graphic materials, the corresponding structural elements of devices for installing parts with orientation along the plane and hole are indicated by the following positions:

1. the case (base) of the device;

2. collet of the extending finger of the installation element;

3. axial slots of the working part of the collet;

4. the inner conical surface of the collet;

5. conical (expandable) part of the rod-rod;

6. cylindrical and threaded parts of the rod-rod;

7. working (expanding) surface of the collet with radial slots;

8. annular grooves of the collet;

9. installed part (blank);

10. through stepwise axial slots of the collet forming its slotted spring;

11. spline groove of the rod-rod;

12. head (multifaceted) for interfacing with a key;

13. Guide sleeve.

I-I - Installation reference plane.

P - Clamping force from the drive (not shown in the drawings).

Δ - The total clearance between the working part of the collet, rod-rod and holes.

Δ ₁ - The gap between the slotted spring collet and the rod-rod.

Δ ₂ - The gap between the slotted spring collet and the part (or guide sleeve).

b - The magnitude (height) of the stepped axial slots 10.

D - The outer diameter of the slotted spring collet,

d - Diameter of the cylindrical part 6 of the rod-rod,

m - The size (width) of the jumpers of the slotted spring collet.

h - Sectional height of the cantilever fragment of the slotted spring of the collet.

β - Skew angle of the cantilever fragment of the slotted spring collet.

In FIG. 1 and 2, in accordance with the requirements of the current GOST 21495-76 (IMS No. 2-82) “Basing and bases in mechanical engineering”, in addition to the above, theoretical basing schemes and distribution of sets of 6 basic reference points are shown (shown as “checkmarks” and “Rhombuses”), depriving the installed part of all 6 possible degrees of freedom (three movements and three turns). The base of the installed part 9 in the devices implementing the proposed method according to FIG. 1 and 2 can be carried out in two main ways:

a) For parts having “long” base holes with a ratio of the length of their generatrix L to the diameter D greater than unity (L / D≥1.0), it is advisable to use the base variant shown in FIG. 1. It involves the implementation of a set of bases, including a technological double guide hidden base, support-thrust explicit base on the plane I-I and support-rotary base, realized due to the action of friction.

b) For parts having “short” base holes with a ratio of the length of the generatrix L to the diameter D of less than unity (L / D <1.0), the base case of FIG. 2, having a set of bases, consisting of a technological installation explicit base along the I-I plane, a double hidden support base along the axis of the hole and a rotary support base, also realized by the action of friction forces. In this case, on the body - the base 1 (see Fig. 2) is placed along the end and the hole coaxially with the collet pin 2 and the rod-rod and fixed on the plane of the rigid guide sleeve 13.

Implementation of the proposed method for installing the part is carried out using the device device (Fig. 1 and 2), including the base body 1, on which the set of mounting elements is fixedly mounted, containing a flat end (lower) rigid support element with a mounting base plane II and at least (at least) at least one expanding installation element oriented along the opening of the base plane II and oriented along the opening of the base body 1 and made in the form of a collet retracting finger having The composition consists of a monolithic collet 2 with symmetrically located radial slots 3, forming axial petals of the collet, and made outside their axial slots 10, forming axial petals of the collet in the form of leaf springs with embedment points in the zone of the jumpers of the slots (see Fig. 4-8).

In the Central hole of the collet 2 is coaxially placed and mates mating working conical surfaces 4 and 5 of the rod-rod. The expanding part of the collet 2 with the working surface 7 is provided to increase its holding ability when clamped by annular grooves 8. The collet body 2 is rigidly fixed (for example, pressed in) in the hole of the base 1 (according to option "a", see Fig. 1) or in the central the hole of the guide sleeve 13 (according to the variant “b”, see Fig. 2) and has a supporting end flange with the possibility of abutment in the base mounting plane II directly or by means of the sleeve 13 through its internal supporting end flange.

The middle part of the collet body 2 between the working surface 7 and its supporting end collar is formed by applying staggered symmetrical stepwise through axial slots 10, forming an axially elastic groove of the collet finger, capable of elastically deforming in the axial direction by reducing the values of the axial slots 10 under the action of the expandable conical part 5 of the rod-rod, evenly and equilaterally eliminate the negative effect by skewing the position of the axial petals of the collet s on the accuracy of alignment of working backlashes in pairings and capable dosylka forces of friction parts 9, to guarantee continuous contact bases and force the closure of a technological subsystem "detail-device". In this case, the initial and working positions of the sections of the slotted spring of the collet 2 are illustrated in FIG. 6 and 7.

To screw the rod-rod into the threaded hole of the rod of a mechanized (for example, hydraulic, pneumatic or electromechanical) power drive (not shown in the drawings), there is a slotted groove 11 or a head 12 (see Fig. 1-3) for the mating key. The base body 1 is rigidly connected to the fixed housing of the power drive. This design is most convenient for installing parts (workpieces) on a blind base hole.

If the installation is carried out through a through hole, then for fixing it is possible to use a replaceable calibrated key of the limit moment (not shown in Figs. 1 and 2) installed in the machine spindle (instead of the working tool) and mating with the conical surface 5 of the expandable rod through the head 12 (shown in dashed lines in FIGS. 1 and 2). The rotation of the machine spindle, transmitted through the torque limit key, either fixes or unfastens the part, depending on the direction of rotation: clockwise or counterclockwise.

In addition, the groove 11 and the multi-faceted head 12 can be used for a version with a manual drive or a torque wrench drive with a limit torque clutch installed in the machine spindle by screwing the threaded part 6 of the rod-rod directly into the threaded hole of the base body 1 or nut, installed in it (not shown in the drawings).

The outer working surface 7 of the collet 2 is made in accordance with the shape of the base hole of the installed part.

For example, in the case of a smooth surface of the base hole, the working surface 7 of the collet 2 can be smooth cylindrical or provided with grooves and ring grooves 8, notches and corrugations, which ensures a more reliable contact of the collet with the surface of the hole of the part 9. This increases the holding capacity of the collet during its operation .

If the mounting hole of the part 9 is threaded, then the working surface 7 of the collet 2 is also made threaded with the same profile and pitch. At the same time, to ensure the possibility of loading - removing the part, the working radial stroke of the petals of the collet 2 should be greater than the thread height.

In the case when, when installing the part through the through base holes, it is not possible to provide the required fastening force and the size of the blowing forces by the above methods, and there is also a technical requirement to prevent damage to the base surface of the hole or insufficient friction between the base surface of the part and the collet petals, etc., you can use the design of the collet, with a protruding shoulder - “mushroom” on the working part, interacting when fixing the part with the end surface of the hole or the groove in it. In this case, such a collar with a collar, which is in a free (undeformed) state, must also have the height of the collar collar less than the working radial stroke of the petals of the collet to enable loading - removal of the part. A similar design of the collet retracting finger can also be used to install blanks on a blind hole, if it has and has a corresponding internal annular undercut or groove. The mounting holes of the part may have chamfers, in this case the collet design must be supplemented with a corresponding conical element mating with the chamfer.

In the case when the installation of the part is carried out through slotted holes or through openings with a keyway, the working surface of the collet 2 must have a reciprocal working surface and is performed taking into account these design features. In this case, the installation can be carried out both on the outer and inner diameter of the spline hole, depending on the accuracy requirements for the part.

The installation method of the part is as follows.

The installed part 9 is placed in the working area of the device, oriented along the plane I-I and at least one hole with an axis intersecting it. At the same time, initial guaranteed radial clearances are provided between the internal expanding mounting elements and the base surfaces of the part openings. The base of the part 9 is carried out by eliminating the radial gaps by expanding the radial lobes of the collet of the expanding mounting elements, its fastening is provided by means of a power circuit between them and the base surfaces of the holes of the part. The sending of the part 9 in the direction of the mounting plane II is carried out due to elastic compression deformation of the axial lobes of the collet 2 of the expanding mounting elements, which is ensured by assessing the design and geometric parameters of the base holes of the part and selecting the corresponding shapes of the working surfaces of the expanding mounting elements, determining the required clamping forces, setting parameters the installation process and the sequence of steps in the installation process by the ratio of the axial and radial stiffness of the expanding collets installation elements greater than or equal to one. To do this, first set the values of the radial clearances between the inner surface of the collet hole and the rod-rod of the expanding mounting element, as well as between the inner surface of the part and the outer surface of the slotted spring made in the middle of the collet body of the expanding mounting element, then design parameters of the slotted groove are assigned spring based on its deformation ability, then by changing the position of the axial petals of the collet of the slotted spring evenly and equilaterally e eliminate all radial clearances and carry out the power circuit of the technological subsystem “part-adaptation”.

Pre-setting the values of the radial clearances (see Fig. 6-9): Δ ₁ - between the inner surface of the collet hole and the rod-rod of the expanding mounting element, and Δ ₂ - between the inner surface of the part or the guide sleeve and the outer surface of the slotted spring allows , since Δ _{1 / 2max} = Δ _min + T _about + T _in , determine and assign reasonable values of the total gap Δ = Δ ₁ + Δ ₂ and the permissible values of deviations of sizes (tolerances) of the corresponding diameters of the holes T _about (the central hole of the collet, based the holes of the part and / or the central hole of the guide sleeve) and the corresponding diameters of the shafts T _in (rod-rod, outer diameter of the collet), which, along with the fittings in their mates, are selected based on the deformation capabilities of the slotted spring, it is guaranteed to eliminate working radial clearances Δ ₁ and Δ ₂ and thereby exclude their negative (negative) effect on the accuracy of centering and basing along the hidden base axis of the hole parts. Otherwise, i.e. without an active selection of gaps, the error of basing will be equal to the possible displacement of the axis of the base part, which is numerically equal to half the maximum value of the total gap Δ = Δ ₁ + Δ ₂ .

The designation of rational constructional parameters for the slotted spring (see Fig. 9: outer diameter "D", diameter of the central hole "d", height of the axial slots "b", values of the width of the bridges "m", section height "h" and the angle of the possible distortion of its cantilever fragment "β", collet material, hardening hardness), made in the middle part of the collet body of the expanding installation element, based on its deformation ability and strength makes it possible to stably elastically deform its cantilever fragments, like arrows b Lock with clamped slits in zones jumpers ends and by skewing the axial position of the collet lobe by an angle β (values within axial slots «b») are uniformly and equilateral eliminate the radial clearances working Δ ₁ and Δ _2.

Devices that implement the proposed method of installing parts, work as follows.

After placing part 9 (see Figs. 1 and 2) along the plane and holes in which the mounting elements are located with a guaranteed clearance (in this case collet 2), the expanding rod-rod receives from the drive a working movement down arrow P. As a result the impact of the conical part 5 of the expanding rod-rod on the inner conical surface 4 of the collet 2, the latter begins to elastically deform in both radial and axial directions. Moreover, the sequence and intensity of this process depends on the ratio of the axial and radial stiffnesses of the expandable mounting element - the collet finger. To implement a rational installation process, the following sequence of steps should be performed: "pre-basing - pre-fastening - retanning - final basing - final fastening".

If the ratio of the axial stiffness of the mounting elements to their radial stiffness is greater than unity, then the installation process of the part along the plane and holes, carried out by the proposed method using collet retracting fingers, is as follows. Under the action of the force P as a result of the action of the conical part 5 of the expanding rod-rod on the inner conical surface 4 of the collet 2, an intense elastic deformation of the petals of the collet 2 (see Figs. 1 and 2) in the radial direction begins at the beginning, while the elastic strain in the axial direction extremely small. The process continues until there is contact between the petals of the collet 2 and the hole of the part 9 (preliminary basing stage). At the contact points of the part with the mounting elements, reactive and friction forces arise, which increase in proportion to the fixing force P and lead to the preliminary fixing of the part 9 through its hole.

After preliminary fixing, the radial stiffness of the collet-part subsystem exceeds the axial stiffness of the collet. The axial force P on the rod-thrust (see Figs. 1 and 2) reaches a value at which the collet 2 begins to elastically deform (compress) with much greater intensity in the axial direction due to a decrease in the “b” value of the stepped radial slots 10 (see Fig. 6 and 7), which ensures a change in the position of the axial petals of the collet, the angular deformation of the leaf springs relative to the places of sealing in the area of the jumpers of the slots, their skew and equilateral sampling due to this (see Fig. 7 and 8), uniform values of the radial gaps between internal turn the specifics of the collet hole and the rod-rod, as well as between the inner surface of the part and the outer surface of the slotted spring of the collet extension finger (and / or additionally provided with a guide sleeve).

The deformation capabilities (abilities) of the slotted spring of the collet are determined and provided by its design parameters, composition and properties of the material.

In this case, the geometrically possible working angle of bias "β _B " (see Fig. 8) of the cantilever fragment of the slotted spring of the collet can be calculated by the formula

,

,

where b is the value of the stepped radial slots 10;

k is the coefficient of working use of part of the size of the slot (k≤1);

D is the outer diameter of the slotted spring collet;

m is the width of the jumpers between the grooves of the slotted spring collet.

For example, for D = 30 mm, m = 6 mm, b = 1.2 mm and k = 0.75, the possible working angle of skew of the axial petals of the collet will be equal to

.

.

When interacting with mating elements (rod-rod, part and / or guide sleeve, see Fig. 7), the bias “β” of the console fragment of the slotted spring of the collet is limited by the working clearances between them. In this case, the actual working angle of bias "β _Ф " (see Fig. 7) of the console fragment of the slotted spring of the collet (without taking into account additional bias due to the influence of contact deformations at the joints) will be limited and can be calculated by the formula

,

,

where Δ = Δ ₁ + Δ ₂ is the total gap between the working part of the collet, rod-rod and holes;

Δ ₁ - the gap between the collet and the rod-rod;

Δ ₂ - the gap between the collet, part and / or guide sleeve;

h is the height of the cross section of the console fragment of the slotted spring collet.

The maximum value of the gaps Δ _{1/2 max} is determined, added and includes (see Fig. 9) the minimum guaranteed working gap Δ _min , which provides the ability to install parts, the permissible size deviations of the dimensions of the corresponding holes T _about (the central hole of the collet, the base hole of the part and / or the central hole of the guide sleeve), the permissible value of deviations of the size of the corresponding shaft T _in (the diameter of the rod-rod, the outer diameter of the collet)

.

.

Tolerances T _about and T _in and landing in the mates are selected or assigned taking into account the properties and based on the deformation capabilities of the slotted spring and the possible skew angle "β" of the axial petals of the collet.

So, for example, when choosing the “stock-collet” pairing for landing d = 20H7 ( ^+0,021 ) / f7 (-0,020 / -0,041), the gap Δ _{1 max} = 0,020 + 0,021 + 0,021 = 0,062 mm, and for the pairing “collet - part / sleeve bore "on fit D = 30H7 ( ⁺⁰ ' ⁰²⁵ ) / f7 (-0.025 / -0.05) clearance Δ _{2 max} = 0.025 + 0.025 + 0.025 = 0.075 mm. In this case, the total clearance between the collet, the rod-rod and the holes of the part / sleeve will be Δ = Δ ₁ + Δ ₂ = 0.062 + 0.075 = 0.137 mm, and the actual working angle of bias is "β _Ф " (see Fig. 7) of the console fragment collet spring will be equal to β _Ф = arcsin (0,137 / 6) = arcsin 0,02283 = 1,5 ° <4,5 ° = β _B. That is, when choosing landings in mates d = 20H7 / f7 and D = 30H7 / f7, the actual working angle of bias will be within the deformation capabilities of the slotted spring and at the same time a triple margin of reliability of its operation will be ensured.

Thus, the implementation of accurate centering by combining the axis of the part with the axis of the mounting element is ensured by uniformly and equilaterally eliminating the negative impact on the accuracy of structural gaps between the elements affecting it. In this case, the uniform and equilateral compensation of the gaps of the slotted spring of the collet is ensured by performing it in the form of through alternating staggered axial stepwise symmetrical slots, forming axial petals of the collet in the form of leaf springs with seals in the zone of the jumpers of the slots and forming the spring part of the axial spring .

As a result of further axial deformation of the collet 2, part 9 is carried away by the frictional forces arising between the surface of the hole of the part and the radial and axial petals of the collet in the direction of the mounting base (I-I) (see Figs. 1 and 2), carrying out the retraction process.

The process continues until the collet exhausts the possibility of elastically deforming in the axial direction. After this, the intensity of elastic deformation of the collet petals sharply increases in the radial direction, which leads to their more reliable contact with the surface of the hole and the final base, as well as to the final fixing

After reaching the calculated value of the fixing force P and creating reliable contact of the bases (the stage of final basing), the forces acting on the part are balanced, and it is finally fixed.

Thus, the necessary sequence of actions of the installation process of the part in the fixture, namely, “preliminary orientation - basing - preliminary fixing - centering by clearing gaps - airing - final basing - final fixing” is fully implemented, ensuring reliable and high-quality installation of the workpiece in the fixture and stable power closure of the technological subsystem "workpiece (part) fixture".

The clamping force P and the geometrical parameters of the construction of the collet are calculated according to well-known methods that are widely represented in various sources of information (technical literature, data from reference books, information from the Internet), for example, "Machine accessories: Reference book". In 2 t. / Ed. Council V.N. Vardashkin (previous) and others. M: Mechanical Engineering, 1984. - 656 p. Goroshkin A.K. "Accessories for metal cutting machines: a Reference." M .: Engineering, 1965, pp. 279-281 and others.

The design parameters of the slotted spring of the collet, its material and properties are assigned (set, selected) based on the deformation ability (ability) to select the available structural radial gaps by changing the position of the axial petals of the collet of the slotted spring of the mounting finger.

The required value of elastic deformation in the axial and radial directions is ensured by setting the design parameters of the collet and the numerical values of the stiffness of the corresponding elements of the device, while maintaining the ratio of axial stiffness to radial greater than or equal to unity. The necessary stiffness and the corresponding values of the deformation of the elements of the sending collet finger with the required fixing force P can be calculated using methods known in the technical literature, for example: Archibald F.R. “Axial stiffness of slotted coil springs”, Proceedings of the American Society of Mechanical Engineers, “Design and Engineering Technology, - 1974, 31, pp. 264-265, I. Birger "Calculation of the strength of machine parts: a Handbook." - M.: Mechanical Engineering, 1979. - 702 s, (pp. 172-173), as well as by the finite element method using the ANSYS computer program or are determined experimentally or by calculation.

After the processes of processing, assembly or control of the rod-rod part (see Figs. 1 and 2) are carried out, the drive receives displacement in the direction opposite to the action of the clamping force R. Collet 2 returns to its original position under the action of elastic forces, its diameter decreases, and appears guaranteed working clearance and the part can be easily removed from the installation elements of the device.

The positive effect of the application of the proposed method for installing parts on a plane and holes is provided by increasing the accuracy of basing, reliability of fastening and efficiency of the installation.

Improving the accuracy of basing is achieved by implementing basing on a hidden base - the geometrical axis of the part’s hole, which eliminates through the uniform and equilateral compensation the negative influence of gaps (between the mounting element and the cylindrical surface of the part’s hole, as well as between the collet finger and its guiding element) on the accuracy of its orientation , as well as ensuring guaranteed continuous contact of the end surface of the part with a flat mounting element.

Ensuring the reliability of fixing is achieved by guaranteed power closure of the technological subsystem "part-adaptation" simultaneously in the radial and axial directions.

A simple installation element, consisting of only three parts, including a monolithic collet finger, is simple in design and construction, reliable in operation, technologically advanced and inexpensive to manufacture, has low cost and maintenance costs, as well as a significant resource for its operation. The design of a compact collet finger makes it possible to use it universally in various devices of devices for mounting parts through holes of various sizes of small size (diameter), various shapes and for blind holes.

The efficiency of the installation is ensured by the use of a mounting element with a collet extending finger, which implements the principle of its action for a complete installation cycle of a part (orientation, basing, fastening, posting) in automatic mode without the use of additional installation devices, which increases the productivity of technological processing, control and assembly operations.

In addition, the proposed method makes it possible to completely eliminate the need for traditional clamps and additional clamps, usually used for clamping when installing body parts along the plane and holes for reliable fastening of the part in the axial (end) direction. In this case, the accessibility (to 5 out of 6 possible) of the sides and surfaces of the part for the supply and operation of the working (processing, measuring, assembly) tool is significantly increased and makes it possible to implement integrated processing, assembly or control.

Currently developed, manufactured and successfully tested pilot laboratory samples of the sending collet fingers that implement the proposed installation method. A virtual simulation of the part installation process and the study of the interaction of the part and the installation element by the finite element method using the ANSYS computer program were carried out.

The use of this technical solution made it possible to increase the accuracy and reliability of the installation of parts in the fixture by an order of magnitude, reduce the cost, and also automate the installation process.

Claims (8)

1. A device for installing parts on a plane and holes for performing technological operations of processing, assembly and control, comprising a base with at least one internal expandable mounting element installed therein, oriented along the mounting plane of the base and configured to be placed in the base hole of the part in in the form of a collet extending finger, having a collet with a rod-rod, which are mated on reciprocal working conical surfaces, radial petals and a supporting shoulder, is made with the possibility of abutment in the installation plane of the base, characterized in that the middle part of the collet between the said supporting collar and the radial petals is made in the form of a slotted spring with alternating staggered axial stepwise symmetrical slots forming axial petals of the collet in the form of leaf springs with places of sealing in the zone of the jumpers of the slots with the formation of the axially elastic spring part of the collet, with the possibility of uniform and equilateral selection of radial gaps trench between the collet and the surface of hole parts dosylka parts and circuit parts of the power from the mounting base plane. 2. A device for mounting a part along a plane and holes for performing technological operations of processing, assembly and control, comprising a base with at least one expandable mounting element installed therein, oriented along the mounting plane of the base and configured to place a part in the form of a collet in the hole a finger that has a collet with a rod-rod, which are mated on reciprocal working conical surfaces, radial petals and a supporting shoulder, characterized in that it is a guide sleeve with a mounting plane and a collar in contact with the mounting plane of the base installed with the middle part of the collet in its inner cavity between said supporting collar and radial petals and with the support of the supporting collar in it, the middle part of the collet is made in the form of a slotted spring with alternating staggered through axial stepwise symmetrical slots forming axial petals of a collet in the form of leaf springs with embedment points in the area of the jumper of the slots with the formation of an axially elastic spring part of the collet, which has the possibility of uniform and equilateral selection of radial clearances between the collet and the surface of the hole of the part, sending the part and force locking of the part with the mounting plane of the guide sleeve. 3. The method of installing parts on a plane and holes for performing technological operations of processing, assembly and control using the device according to claim 1 or 2, including placing the part with orientation on the plane and at least one hole with an axis intersecting it and providing initial guaranteed radial the gaps between the base surfaces of the holes of the part and the internal expanding installation elements of the said device, the shape of the working surfaces of which are selected in accordance with the design and the geometric parameters of the base holes of the part, while the design parameters of the slotted spring of the collet of the expanding mounting element are set based on its deformation ability and the specified values of the radial clearances between the inner surface of the collet hole and the rod-rod of the expanding mounting element, as well as between the inner surface of the part or the guide sleeve and the outer surface of the slotted spring, and by setting the ratio of the axial and radial stiffness of the expanding collet novochnyh elements greater than or equal to one set following the sequence of steps of the installation process: - preliminary basing of the part by expanding the radial petals of the collet of the expanding installation elements with the elimination of radial gaps, - preliminary fixing of the part by means of a power circuit between the radial petals of the collet and the base surfaces of the holes of the part, - sending the part in the direction of the installation plane by means of elastic compression deformation of the axial lobes of the collet of the expanding installation elements, - the final base of the part by changing the position of the axial petals of the slotted spring collet with uniform and equilateral elimination of all radial clearances and - the final fixing of the part by means of its power circuit with the said device when the specified clamping force is reached.

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