RU44405U1 - MONOBLOCK SEAL - Google Patents

Abstract

The utility model relates to hardware used for locking and simultaneously sealing doors of covered wagons, containers, tank hatches, helms of hopper cars, as well as for protecting transported goods in other modes of transport. The monoblock seal contains a housing, a rope segment, at least one spring-loaded locking element with the possibility of its interaction with the free end of the rope, equipped with discrete stationary ring elements. The free end of the rope is made reduced, the diameter of the fixed annular elements exceeds the diameter of the reduced free end of the rope, the extreme locking ring elements are spaced from each other, overlapping the inlet and outlet openings of the through channel when the rope is placed in it, and fixing ring elements made of the location of the locking element between two adjacent locking ring elements, and the distance between them does not exceed the diameter of the feet of the element. Fixed ring elements are made in the form of split or continuous rings, collets or crackers. The fixed ring elements are made of a material whose strength and deformation properties exceed those of a rope. The reduction of the free end of the rope is carried out by rolling, crimping or crimping.

Description

The utility model relates to hardware used for locking and simultaneously sealing doors of covered wagons, containers, tank hatches, helms of hopper cars, as well as for protecting transported goods in other modes of transport.

A cable seal is known that contains a segment of a rope with a stop fixed at one end, a body with a through channel for passing the free end of the rope and communicating with it located at an angle of at least one channel for a spring-loaded locking element in the form of a body of revolution, which is intended for interaction with the free end of the rope (RU No. 10146, U1, B 60 R 11/00, 1999).

A disadvantage of the known filling is the inconvenience of filling, since locking it requires not translational, but rotational-translational movement, and insufficient mechanical tensile strength, because when you try to force the rope out of the body, the balls begin to move to jam, i.e. go from the inclined holes to the axial one, and due to technological tolerances on the drilling angles of the inclined holes, one of the balls starts to outpace the others and deform the wires from which the rope is twisted, and the more it leads the rest of the balls, the stronger the deformation of the rope at the point of interaction with this ball and the faster the ball will cut the rope.

Thus, the technical problem, which the utility model is aimed at, is reduced to the development of a device for locking and sealing, in which these shortcomings would be eliminated, i.e. the technical result achieved by the utility model consists in increasing the mechanical tensile strength, eliminating the need for rotation of the body around the rope when locking a one-piece seal and in a significant increase in the reliability of its operation.

The above technical result is achieved due to the fact that the monoblock seal contains a housing, a piece of rope, at least one spring-loaded locking element with the possibility of its interaction with the free end of the rope, equipped with discrete stationary ring elements.

The free end of the rope is made reduced, the diameter of the fixed ring elements exceeds the diameter of the reduced free end of the rope, the extreme locking ring elements are located at a distance from each other, overlapping the inlet and outlet openings of the through channel when the rope is placed in it, and fixing ring elements are installed between them from the location conditions a locking element between two adjacent locking ring elements.

The distance between two adjacent locking ring elements does not exceed the diameter of the locking element.

Fixed ring elements are made in the form of split or continuous rings, collets or crackers.

The fixed ring elements are made of a material whose strength and deformation properties exceed those of a rope

The reduction of the free end of the rope is carried out by rolling, crimping or crimping.

The implementation of the free end of the rope with fixed fixed on it discrete stationary ring elements, the diameter of which exceeds the diameter of the reduced free end of the rope, completely eliminates the possibility of power removal of the rope from the body, i.e. provides increased reliability of the one-piece seal due to the fact that the locking elements in the closed state are located between two adjacent locking ring elements. In this case, the locking elements, when trying to forcefully move the case along the rope to open, are sequentially assembled on one of the fixed fixing ring elements and begin to interact with it at not one, but at once at three points simultaneously, therefore, the rope does not deform strongly and withstands the seal significantly greater mechanical tensile strength.

The presence of extreme locking ring elements, which in the closed state overlap the inlet and outlet openings of the through channel, also increase the reliability of the monoblock seal due to the formation of a minimum gap between the extreme locking ring elements and the wall of the through channel, through which it cannot penetrate into the housing using a flat power tool seems possible.

Placing two adjacent locking ring elements at a distance not exceeding the diameter of the locking element does not allow for

unauthorized force extraction to pull the rope from the housing by the amount at which the extreme locking ring elements will not overlap the inlet and outlet openings of the through channel.

The implementation of fixed ring elements in the form of split or continuous rings, collets or crackers expands the range of applied fixed elements and further increases the reliability of the seal due to the deeper location of the locking element between the fixed elements.

The execution of fixed ring elements of a more durable material in comparison with the rope makes it difficult to remove it from the body, because when the rope is pulled out of the case by force, the rope is slightly deformed, and the fixing ring elements are not deformed and the locking elements securely hold the rope in the case.

The reduction operation by running, crimping or crimping allows you to use various options for machining the free end of the rope.

The utility model is illustrated by drawings, where:

figure 1 shows a General view of a monoblock seal in cross section;

figure 2 is a section aa in figure 1.

The monoblock seal contains a housing 1, a segment of a rope 2, a through channel 3, a blind channel 4, in which a spring 5 and a locking element 6 in the form of balls, a tip 7 of a rope, a cavity 8 for a tip, a reduced free end 9 of a rope are placed.

At the reduced free end 9 are fixed locking ring elements 10 and 13 and the locking ring elements 11 and 12 in the form of continuous rings. In the housing 1 from the side of the inlet 16 there is a sleeve 14, which is rolled by the end face 15 of the housing 1.

Monoblock seal works as follows.

At one end of the rope 2, a tip 7 is fixed, which is installed in the cavity 8 of the housing 1 with a gap and the possibility of its rotation around the axis. The reduced free end 9 of the rope 2 with locking and fixing ring elements 10, 13 and 11, 12 is passed through the eyes of the locking unit (not shown in Fig.) And inserted into the inlet 16 of the housing 1. At the same time, three balls of the locking element 6 (see figure 2) fall into the helical grooves of the rope and as it moves through the body, the tip 7 rotates in the cavity 8, which ensures the safety of the rope, i.e. he does not unwind. When moving the rope balls

compress the spring 5 and they move into the blind channel 4, freeing the passage to the reduced free end 9. After introducing the free end 9 of the rope 2 into the eyes, the balls are located between the locking ring elements 11 and 12, and the locking ring elements 10 and 13 are located in the input zone and outlet openings of the through channel 3.

When trying to forcefully remove the free end 9 of the rope 2 from the through channel 3, the balls first jam the free end 9 of the rope 2 and almost simultaneously abut the fixing ring element 11 and prevent it from being removed from the housing 1.

Such a constructive solution provides an increase in the mechanical tensile strength of the device, eliminating the need for rotation of the housing relative to the rope when the locking and sealing device is closed and significantly increases the reliability of the device.

Claims (5)

1. A one-piece seal containing a housing, a piece of rope, a spring-loaded locking element with the possibility of its interaction with the free end of the rope, equipped with discretely arranged fixed ring elements, characterized in that the free end of the rope is made reduced, the diameter of the fixed ring elements exceeds the diameter of the reduced free end of the rope , the extreme locking ring elements are located from each other at a distance that ensures the overlap of the inlet and outlet openings through Channel when placing it in the rope, and between them are installed retaining ring members from the condition of location of the locking member between two adjacent annular retaining elements. 2. Monoblock seal according to claim 1, characterized in that the distance between two adjacent locking ring elements does not exceed the diameter of the locking element. 3. Monoblock seal according to claim 1, characterized in that the stationary ring elements are made in the form of split or continuous rings, collets or crackers. 4. The one-piece seal according to claim 1, characterized in that the stationary annular elements are made of a material whose strength and deformation properties exceed the similar properties of the rope. 5. Monoblock seal according to claim 1, characterized in that the reduction is carried out by rolling, crimping or crimping.