RU54644U1 - DEVICE FOR CONNECTING FIGURE HOLLOW BARS - Google Patents

Abstract

The invention relates to devices for connecting elements of frame structures of aluminum or steel profile.

The essence of the utility model: in a device containing a housing with wedge-shaped platforms, a spring element is placed in the housing with the possibility of longitudinal movement, having hooks at one end and hooks and an eccentric bolt mounted in a figured hole at the other end of the spring element, the spring element is made with three hooks, of which two lateral ones are directed with the open part in one direction, and the middle one is in the opposite direction, and in the case there are three wedge-shaped platforms intended for interaction Twi with each of the hooks, respectively. In this case, two lateral wedge-shaped platforms are placed on one inner surface of the housing, and the middle platform is on the opposite inner surface of the housing. The width of both side hooks of the spring element is the same, and the middle hook of the spring element is wider than the side hooks.

Effect: simplify the design of the device, increase the reliability of the connection of the rods by ensuring the symmetry of the load distribution in the hooks of the device, as well as reducing the cost of its manufacture and use.

Description

The utility model relates to devices for connecting elements of frame structures made of aluminum or steel profile and can be used, for example, in the construction of partitions, boxes and other objects in exhibition rooms for fast and reliable fastening of horizontal or inclined runs (rods) to vertical racks.

A device for a frame structure according to US patent No. 4345849, F 16 B 7/04, 1982, designed to connect and disconnect the components of the structure of the rods installed in the supporting rods. The device contains a support element with an eccentric element installed in it and a spring coupler (holder) covering the support element and installed with the possibility of its movement in the longitudinal and transverse directions depending on the rotation of the eccentric. Access for its rotation is provided on one side of the bar in which the device is located. The spring coupler is made in the form of a U-shaped bracket, including a pair of levers, some ends of which are connected by a jumper, and the other, hooking ends are hook-shaped. A groove is made in the spring coupler to accommodate the eccentric, and the eccentric itself is made of two flat cams, rigidly interconnected by a support pin with an internal hole, and a sleeve installed in this hole. On the outer surface of the sleeve and on the inner surface of the pin, grooves are provided for the interaction of the sleeve and the pin. When the eccentric is turned, its cams, interacting with the back wall of the spring coupler, move it away, S-shaped bends of the levers crawl onto the central bridge of the support element, move apart in the transverse direction and engage on the walls of the T-shaped groove of the other rod.

To install the specified device in the supporting rod, a spring coupler with the support element and the cam part of the eccentric inserted in it is placed in the cavity of the rod at its end, after which the sleeve is inserted through the hole in the rod body into the pin hole of the eccentric element. In this case, an almost integral structure is obtained, i.e. remove the fixture from

it is very difficult to install the rod after its installation, and in the event of failure of one of the devices, it is necessary to replace the entire rod, which increases the assembly time of the entire frame structure, and also requires the presence of additional rods, thereby increasing the total cost of mounting the structure.

Known locking device of the German company "Octanorm Nordic" (see. Product catalog of the specified company, 1994, article Z961), comprising a housing with a spring coupler installed in it and an eccentric bolt located in the spring coupler hole. The eccentric bolt contains a head, an axis and two cams, an outer and an inner one, located on the axis of the bolt one above the other. The spring coupler is made with two legs, separated by a longitudinal groove, and is equipped with a springy bend in contact with the outer cam of the eccentric bolt and located at the end of the groove where the legs are connected. The rear end of the spring coupler is made with a bend parallel to the plane of the coupler.

The locking device is tightened by turning the eccentric with a special key. When turning the eccentric, the outer cam interacts with the folding of the spring coupler and moves it, while the tabs of the coupler, having an S-shape, crawl onto the inclined platforms of the case, move apart and hook with their hooks on the walls of the groove in the rack. With a further turn of the eccentric and the corresponding movement of the screed, the run is clamped to the stand with a force determined by the elastic deformation of the screed. In the initial state, the screed moves forcibly due to the interaction of the outer (upper) cam of the eccentric with a special extrusion in the screed.

The inner (lower) cam of the eccentric serves to limit its rotation in the range from 0 to 180 °, which is due to the interaction of the cam with the walls of the figured hole in the screed. The support of the eccentric in the transverse direction is carried out by folding in the screed, resting on the inner wall of the housing.

In the indicated locking device, when the eccentric is pressed with a force exceeding the back-up force and the key is turned simultaneously, the upper wall of the casing is often deformed, as a result of which the lock is jammed in the rod and fails. In addition, due to the small size of the inner cam compared to the permissible clearances, when the key is applied with considerable force, the eccentric bolt often turns, which increases the assembly time

exhibition equipment and reduces the reliability of the connection. Details of the castle have a rather complicated configuration; their manufacture requires expensive equipment, leading to a rise in the cost of the castle connection.

Closest to the technical nature of the claimed is a device for connecting curly hollow rods according to USSR patent No. 1838765, F 16 B 7/22, 1993, containing a housing mounted in it with the possibility of longitudinal movement of the spring element (profile plate) having one end has two hook hooks, and an eccentric bolt located on the other end of the spring element. The longitudinal movement of the spring element is provided by the rotation of the bolt.

In the indicated device, in the spring element (plate), a blind longitudinal slot is made on one side, dividing it into two strips, the end sections of which are bent in the form of hooks and open ends are directed towards each other. Closer to the other end of the plate, an elongated window is made in it, through which an eccentric bolt passes. A loop is made at the other end of the plate, the free end of which is located at right angles to the abutment surface of the plate and also passes through an elongated window in the plate. In this case, the portion of the end of the loop that extends beyond the abutment surface serves as the rear control protrusion for the eccentric disk of the bolt; on the side of the window opposite this protrusion, a front control protrusion is made, and the eccentric disk rests on the thrust surface of the plate and is located between these protrusions.

The eccentric bolt contains a head, an upper cam made in the form of the above-mentioned eccentric disk, and a cylindrical support neck, equipped with a stop on the disk side, which can be moved through a one-sided notch of the plate window, and is designed to limit the rotation of the bolt over 180 °. However, the dimensions of this stop, which functions as a lower cam, are relatively small compared to the clearance of the plate window, and if excessive torque is applied to the eccentric bolt, the stop can slip through the bounding edge of the window, causing the bolt to rotate and weaken the clamp position of the device.

The housing of the device is made with two wedge-shaped surfaces, each in contact with the inclined portion of the corresponding hook. When moving the spring element in the longitudinal direction, its hooks are displaced relative to each other along the wedge-shaped surfaces in the direction transverse to the element. The device is installed in the support rod, then the head

hooks lead into the groove of the second rod and by turning the eccentric bolt push the spring element into the housing. In this case, the hooks are moved apart relative to each other, and the ends of their heads engage on opposite walls of the groove of the second rod.

However, practice shows that the efforts of pressing the inclined sections of the hooks to the wedge-shaped platforms are not the same, and one of them, pressed to the upper platform, is subject to more twisting. This creates a torque acting on the screed and tends to deploy it in the transverse direction. This can lead to distortion of the screed in the device body and, thus, to jamming of the device, which reduces the reliability of the connection.

In addition, the manufacture of a spring element with a loop and a front control protrusion as described above is very low-tech, because requires several operations and expensive equipment. At the same time, for reliable fastening of the rods of the entire frame structure in each fixture, it is necessary to strictly observe the distance between the rear control ledge and the end edges of the hooks that press the walls of the second rod to the end side of the support rod, which is difficult to achieve due to the variation in tolerances during several bending operations. If this condition is not fulfilled, then either the rods will be loosely drawn towards each other, or hooking of the walls of the second rod will not occur at all. This leads to the need to replace the fixture, which also increases the labor and assembly costs of the frame structure of the exhibition equipment and reduces the reliability of the connection structure as a whole.

The utility model solves the problem of simplifying the design of the device, increasing the reliability of the connection of the rods by ensuring the symmetry of the load distribution in the hooks of the device, as well as reducing the cost of its manufacture and use.

This is achieved by the fact that in the device for connecting curly hollow rods comprising a housing with wedge-shaped platforms made therein, a spring element is placed in the housing with the possibility of longitudinal movement, having hooks at one end and an eccentric bolt mounted in the figured hole on the other end of the spring element and made in the form of sequentially located head, cam and support neck, and in the middle part of the spring element is made a support bend in contact with the inner surface of the housing, a spring element is arranged

three hooks, of which two lateral ones are directed by the open part in one direction, and the middle one is in the opposite direction, and three wedge-shaped platforms are made in the case, designed to interact with each of the hooks, respectively. In this case, two lateral wedge-shaped platforms are placed on one inner surface of the housing, and the middle platform is on the opposite inner surface of the housing. The width of both side hooks of the spring element is the same, and the middle hook of the spring element is wider than the side hooks.

The rear end of the spring element is 180 ° bent, and the back end is bent with a protrusion designed to limit the rotation of the eccentric bolt. The supporting surface of the limb of the rear end of the spring element in contact with the eccentric bolt is made radial, and the edge of the figured hole of the spring element opposite the bending of the rear end of the spring element is molded to form a front stop for the eccentric bolt.

The reference bending of the spring element is placed at the base of the middle hook and bent to the side opposite to the bending of the rear end of the spring element.

To support the eccentric bolt on the inner surface of the casing, a tide was made, and in the rear part of the casing, a sample was made with the radius part of the surface in contact with the head of the eccentric bolt.

In this case, the cam of the eccentric bolt is made in the form of an ellipse, the small radius of which, interacting with the thrust surfaces of the spring element, is commensurate with the radius of the rounded portion of the bending of the spring element.

The device is illustrated by drawings, in which figure 1 shows the claimed device in a perspective view; figure 2 is the same device in plan; figure 3 is a longitudinal section of the device along the line aa (in the position ensuring its installation and dismantling); figure 4 is a view of the device along arrow B; figure 5 is a longitudinal section of the device in the working (tightened) position; figure 6 is a view of the device along arrow B; 7 is a plan view of a spring coupler; on Fig - spring screed, side view.

A device for connecting curly hollow rods, for example, for attaching a run 1 to a stand 2 having a T-shaped groove, comprises a housing 3 with two lateral wedge-shaped platforms 4 located on the lower inner surface of the housing 3, an average wedge-shaped platform 5, located on the upper inner surface of the housing 3, and locking

protrusions 6. In the housing 3, a spring element 7 is mounted, arranged for its longitudinal movement and having a hook hook at one end, and an eccentric bolt 8 placed on the other end of the spring element 7.

At one end, the spring element 7 is divided into three strips: two side strips 9 and a middle stripe 10, each of which is bent symmetrically relative to the plane of the spring element, with the side strips 9 curved in one direction and the middle stripe 10 in the opposite direction.

The end sections of these strips are curved in the form of U-shaped side hooks 11 located on the strips 9 and the middle hook 12 located on the strip 10. In this case, the two side hooks 11 and the middle hook 12 with open ends are directed towards each other, and have inclined sections 13, 14 and their longitudinal sections 15 and 16, respectively. To ensure a more uniform area of the support of the hooks on both sides of the T-groove, the width of both side hooks 11 of the spring element 7 is the same, and the middle hook 12 is made wider than the side hooks.

The thickness d of each of the hooks 11 and 12 is slightly smaller than the width of the bore hole T-shaped groove 17, made in the rack 2, connected to the run 1. In the initial (extended) position of the spring element 7, the heads of the hooks 11 and 12 are located relative to each other so that their total thickness does not exceed the thickness d of one hook. Each of the longitudinal sections 15 and 16 of the strips 9 and 10 is bent in the middle part and is located approximately at the same level with the open end of the corresponding hook 11 or 12, and the strips 9 and 10 form an S-shape with crossed inclined sections 13 and 14.

In the Central part of the spring element 7 is made spring support bending 18, the edges of the cutting which are limited by technological holes. This reference bend 18 is located at the base of the middle hook 12 and is designed to create a spring action (back pressure) on the eccentric bolt 8 mounted in the spring element 7. For this, the bend 18 with its free end 19 is in contact with the possibility of sliding with the inner surface of the housing 3, and at the point of contact with the housing, it is curved more than strips 9 and 10.

The eccentric bolt 8 contains a sequentially located head 20 with a hole for a multi-slotted screwdriver or key, a cam 21 made in the form

the eccentric disk and resting on the spring element 7 with its inner surface 22, and the support neck 23, coaxial with the bolt head 20 and installed in the hole 24 in the rear wall of the housing 3. The support neck 23 on the end surface is provided with a groove for assembly. Support eccentric bolt 8 in the transverse direction is based on the inner surface of the housing 3 by folding 18 of the spring element 7.

Behind the reference bending 18 in the element 7, a control figured hole 25 is made through which the eccentric bolt 8 passes. The hole 25 has a shape elongated in the longitudinal direction of the spring element, and a recess 27 for interaction is made at one end thereof close to the rear end face 26 of the spring element. with a cam 21, designed to limit the rotation of the eccentric bolt 8 in the range from 0 ° to 180 °.

In order to ensure reliable interaction of the cam 21 with the hole 25, the thickness of the cam slightly exceeds the thickness of the spring element 7.

The rear end 26 of the spring element 7 is 180 ° bent, and the rear end bend 28 is made with a protrusion 29, designed to limit the rotation of the eccentric bolt. The supporting surface of the limb 28 in contact with the eccentric bolt 8 is made radial. In addition, the cam 20 of the eccentric bolt 8 is made in the form of an ellipse, the small radius of which, interacting with the thrust surfaces of the spring element 7, is commensurate with the radius of the rounded portion of the bend 28 of the spring element.

In the place of the jumper between the support bending 18 and the figured hole 25 of the spring element 7, the edge of the figured hole opposite the bending 28 of the rear end 26 of the spring element is molded to form a front stop 30 for the eccentric bolt.

To lock the lock in the closed state, i.e. to prevent pressing of the eccentric bolt 8, when the device is inserted into the rod 1 and the head 20 of the bolt 8 is placed in the fixing hole of the rod, there are locking protrusions 6 made in the rear part of the housing 3, preventing the spring element 7 from moving in the transverse direction. When turning the eccentric bolt 8, the rear end 26 of the spring element 7 freely passes over the locking protrusions 6, and pressing the eccentric 8 becomes impossible. Moreover, the end face 26 is above the protrusions 6 with a very small longitudinal movement of the screed, equal to, for example, 0.1 mm This distance should be small.

so that the screed does not have time to unfold under the action of the torque arising from the divorced hooks 11 and 12.

On the outer part of the housing 3, protrusions 30 are made, the ends of which in the engagement position are adjacent to the end side of the run 1. The protrusions 30 are located on both sides of the hooks 11 and 12 at approximately their level in the extended position, and the width of the protrusions 30 corresponds to the width b of the passage opening T -shaped groove 17, made in the rack 2. When mounting the frame structure, the protrusions 30 are included in the groove 17 of the rack 2 and thereby prevent warping of the run 1 with respect to the rack 2.

To install the locking device in the side wall of the rod (run 1), a fixing hole 31 is made for the eccentric bolt head 20 protruding beyond the dimensions of the device. When the eccentric head 20 is pressed, its protruding part is sunk into the housing 3, and the device is freely inserted into the rod. When the head 20 of the bolt 8 coincides with the fixing hole 31 in the run 1 under the pressure of the spring element 7, the eccentric bolt 8 is pushed out of the housing 3, and its protruding part is placed in the fixing hole of the run.

To rotate the eccentric bolt 8 in the head 20, a blind shaped hole 32 is made for the installation key or multi-slotted screwdriver.

The device works as follows. The locking device is tightened (closed) by turning the eccentric bolt 8 with a special key half a turn in the direction of arrow 33. When the eccentric is rotated, its cam 21, interacting with the walls of the control hole 25 of the spring element 7, pushes it in the direction of the groove 17 of the rack 2 by a certain distance. In this case, the inclined sections 13 and 14 of the S-shaped strips 11 and 12 of the element 7 crawl onto the wedge-shaped platforms 4 and 5 of the housing 3, move apart and hooks 9 and 10 hook onto the walls of the groove 17 in the rack 2. With a further rotation of the eccentric bolt 8 and the corresponding the movement of the spring element 7 is clamped run to the rack with a force determined by the elastic deformation of the element 7. Opening (opening) of the locking device occurs in the reverse order. In the initial state, the screed moves forcibly due to the interaction of the cam 21 of the eccentric bolt 8 with the figured hole 25 in the spring element.

Thus, the implementation of the spring element with three hooks directed open part towards each other, and not with two, as in the known technical solutions, with three corresponding hooks

wedge-shaped platforms made in the case, as well as the shape of the hooks (their various widths) make it possible to make the load on the hooks of the spring tie more uniform (symmetrical) and, thereby, reduce the deformation of the profile by increasing the area of the hooks on the groove walls in the run, which significantly increases the reliability of the device and reduces the cost of its manufacture, and also simplifies the design and manufacture of the device.

Claims (12)

1. A device for connecting curly hollow rods, comprising a housing with wedge-shaped pads made therein, a spring element placed in the housing with the possibility of longitudinal movement and having hook hooks at one end, and an eccentric bolt mounted in the shaped hole at the other end spring element and made in the form of sequentially located head, cam and support neck, and in the middle part of the spring element is made a supporting bend in contact with the inner surface of the body whisker, characterized in that the spring element is equipped with three hooks, of which two lateral are directed open part in one direction, and the middle - in the opposite direction, and in the body there are three wedge-shaped platforms designed to interact with each of the hooks, respectively. 2. The device according to claim 1, characterized in that two lateral wedge-shaped platforms are placed on the same inner surface of the housing, and the middle platform is on the opposite inner surface of the housing. 3. The device according to claim 1, characterized in that the rear end of the spring element is bent 180 °. 4. The device according to claim 3, characterized in that the limb of the rear end of the spring element is made with a protrusion designed to limit the rotation of the eccentric bolt. 5. The device according to claim 3, characterized in that the supporting surface of the limb of the rear end of the spring element in contact with the eccentric bolt is made radius. 6. The device according to claim 1, characterized in that the edge of the figured hole of the spring element, opposite the bending of the rear end of the spring element, is molded to form a front stop for the eccentric bolt. 7. The device according to claim 1, characterized in that the width of both side hooks of the spring element is the same. 8. The device according to claim 7, characterized in that the middle hook of the spring element is made wider than the side hooks. 9. The device according to claim 1, characterized in that the reference bending is located at the base of the middle hook of the spring element and bent to the side opposite to the bending of the rear end of the spring element. 10. The device according to claim 1, characterized in that a tide is made to support the eccentric bolt on the inner surface of the housing. 11. The device according to claim 1, characterized in that in the rear of the housing a sample is made with a radius part of the surface in contact with the head of the eccentric bolt. 12. The device according to claim 1, characterized in that the cam of the eccentric bolt is made in the form of an ellipse, the small radius of which is commensurate with the radius of the rounded portion of the limb of the spring element.