RU2113580C1 - Ice breaking device - Google Patents

Abstract

FIELD: breaking ice in water areas. SUBSTANCE: this is intended for clearing frozen water basins from ice cover. Device 1 has moving part 6 which is made up of pointed working member 7 and vertical housing 8 in which vibrating hammer 9 is installed. Vibrating hammer is connected by cable 10 with source of electric power. Device is provided with float 14 made with flat horizontal upper and lower end faces and circular vertical cylindrical hole 15. Working member 7 is secured to lower part of vertical housing 8 which is made round and cylindrical and installed in hole 15 of float 14 for possible longitudinal reciprocating motion. Upper part of housing 8 is made in the form of disk 16 of diameter which is larger than diameter of hole 15 in float 14. Provided on lower surface is resilient shock-absorbing ring 17. EFFECT: higher efficiency in operation. 4 cl, 4 dwg

Description

 Known ice-breaking device attached to the support of a hydraulic structure and containing a vibrator, consisting of a housing with a plate, cargo, springs and a sealing cuff made in the form of a flexible elastic shell, the internal cavity of which communicates through a pneumatic distributor with a source of compressed gas [1].

 Inside the body of the ice-breaking device there is a working chamber, the volume of which is limited by a cuff, a load and a plate, and the tightness of the working chamber is ensured by the presence of a cuff. The working chamber during operation of the device is filled with water through the valve and raises the load, compressing the springs. When lowering the load, the inner cavity of the cuff begins to communicate with the atmosphere and the cuff, due to elasticity, acquires its original shape and position. At the same time, the cuff is depressurized by the working chamber. The control valve closes the water supply, and the water in the working chamber quickly leaves it through the control valve and openings in the housing.

 As a result, the load falls and hits the plate, and its kinetic energy is spent on the destruction of ice.

 The disadvantage of the device in question is the lack of its necessary reliability, since it, despite the intense vibration during operation, must have trouble-free communication with pressure pneumatic and hydraulic lines, which in such conditions is almost impossible.

 It is also known a device for the destruction of thawed and frozen soils, including ice, containing a vertical casing with an eye in the upper part for connection to a truck, a vibratory hammer installed in the casing and connected by a cable to an electric power source, and a pointed working body attached to the lower part of the casing [2 S. 245-250, Fig. 8.12, 8.13, 8.17, taken as a prototype].

 The disadvantage of this device is that during its operation it is difficult to meet the requirement that the mass of soil or ice would be destroyed exactly in the selected place. In addition, to increase the efficiency of the device, it is also required that it be installed at a certain angle to the surface of the soil or ice massif, and this angle should also be maintained during the destruction of the indicated massif.

 Moreover, it can be considered that if the device in question is used in operation without special auxiliary equipment, consisting of a guide support frame with a winch mounted on it for lifting it, then the reliability of the device will be insufficient.

 The objective of the invention is to increase the reliability of the device for the destruction of ice in the freezing waters.

 To increase the reliability of the device for breaking ice in a known device containing a vertical casing with an eye for connecting to a truck, a vibration hammer installed in the casing and connected by a cable to an electric power source, and a pointed working body attached to the bottom of the casing, according to the invention, the device equipped with a float with flat horizontal upper and lower ends and a round vertical cylindrical hole, the casing is made round cylindrical and installed in the hole stii displacer for longitudinal reciprocating movement, the upper housing portion is formed as a disc with a diameter larger than the hole of the float, and with a shock-absorbing elastic ring on the lower surface.

 Additionally, the working body can be equipped with a heater installed inside it, made in the form of an electric spiral.

 The float can also be made with eyes for attachment to a truck.

 In addition, the float can be made hollow, filled with a substance having a lower density compared to the density of water, mainly polystyrene.

 The following is a discussion of the device used to break ice in the freezing waters of berthing facilities.

 The proposed device for the destruction of ice is illustrated by drawings, where Fig. 1 shows in cross-section a device mounted on the surface of a selected section of an ice field during its operation, Fig. 2 shows a plan in plan, and Fig. 3 shows in cross section the final stage of installing the device on the surface of the selected area of the ice field, when after installation is completed on this surface of the float in a round vertical cylindrical hole in the float using a cargo boom of a truck introduced the movable part of the device.

 In figure 3 A is the distance from the line of the cordon of the structure to the strip on the ice field, within which ice should be destroyed; B is the width of the specified strip; C is the width of the strip located outside the maximum reach of the cargo boom of the gantry crane, in which the ice is destroyed by the icebreaker; dashed lines show the subsequent positions of the float and the cargo boom of the gantry crane when moving the device to a new place within the width of the area where the ice should be destroyed.

 The device 1 used to destroy the ice field 2 at the berth structure 3 and moved by a lifting vehicle, such as a gantry crane 4, equipped with a cargo boom 5, has a movable part 6, including a pointed working body 7 and a vertical casing 8, in which vibration hammer 9 connected by cable 10 to a source of electricity.

 The working body 7 is attached to the lower part of the vertical casing 8, having in the upper part an eyelet 11 for connecting the movable part 6 of the device 1 and the hook 12 of the truck, for example a gantry crane 4, using slings 13.

 The device 1 is also equipped with a float 14 having a lifting force exceeding the weight of the movable part 6 of the device 1, together with the dynamic component arising from vibration of the vibratory hammer 9, and made with flat horizontal upper and lower ends and with a round vertical cylindrical hole 15 made in the central float parts 14.

 In the movable part 6 of the device 1, the vertical casing 8 is also made round cylindrical and has a diameter that allows you to enter the movable part 6 into the hole 15 of the float 14, and when bringing the device 1 into working position, the vertical casing 8 should be installed in the hole 15 of the float 14 with the possibility of longitudinal reciprocating movement.

 The upper part of the vertical casing 8 is made in the form of a disk 16 with a diameter larger than the diameter of the hole 15 of the float 14, and with a shock-absorbing elastic ring 17 on the lower surface.

 Additionally, the working body 7 of the movable part 6 of the device 1 can be equipped with a heater installed inside it, made, for example, in the form of an electric spiral 18.

 The float 14 may also be provided with eyes 19 for its independent connection with the help of slings 20 to the hook 12 of a truck, for example a gantry crane 4.

 In addition, the float 14 can be made hollow, with a filler 21 from a substance having a lower density compared with the density of water, mainly from polystyrene.

 The device for the destruction of ice as follows.

 Prior to the introduction of the device 1 into operation, the location and size of the strip on the ice field 2 at the building 3, where the ice should be destroyed, and the length of each of its constituent sections, as well as the direction in which the device 1 will move during operation, are determined.

This is guided by the following considerations: the distance A from the cordon line of structure 3 to the strip on the ice field 2, within which ice should be destroyed, is established based on shipping requirements, and also based on the need to exclude the possibility of damage to the structure of structure 3 during operation of device 1 for breaking ice; at the same time, the technical characteristics of the truck used, such as the load capacity and reach of the boom 5, as well as the actual location of the truck relative to the cordon line of structure 3, must be taken into account;
the width B of the indicated strip, equal to the width of the separate adjacent sections of the ice field 2 on which the ice is to be destroyed, is determined in accordance with the requirements of shipping, taking into account the carrying capacity and departure of the cargo boom 5 of the truck;
the length of individual adjacent sections of the ice field 2 along the line of the cordon of structure 3, on which ice should be destroyed, is established based on the radius of action of the truck;
the direction in which the device 1 will move is determined based on the local conditions of the work; so, for example, if there is a current in the water area, the direction opposite to the direction of the current is chosen.

 The choice of the ice field section 2, where the ice should be destroyed in the first place, is made taking into account the state of the ice, which for this should be previously investigated, for example, using ultrasonic devices, and as such a section, the ice field section 2 s weakened by cracks should be taken smallest ice thickness.

 Next, a truck equipped with a cargo boom 5 is brought to a selected section of the ice field 2, where the ice should be destroyed first, for example, if the ice field 2 is located at the berthing structure 3, the gantry crane 4 with the crane suspended from it hook 12 using slings 20 with a float 14.

 Then, the float 14 with the cargo boom 5 of the gantry crane 4 is smoothly lowered onto the ice field 2 and set it on the surface of that section of the ice field 2, within which it is planned to destroy the ice, and the installation of the float 14 is carried out so that it rests with its lower flat end on the specified surface. After that, the float 14 is discharged.

 Further, to the surface area of the ice field 2, on which the float 14 is already installed, the movable part 6 of the device 1 is also delivered by the cargo boom 5 of the portal crane 4.

 Then the movable part 6 of the device 1 with a cargo boom 5 of the gantry crane 4 is introduced tapering down by the working body 7 into a round vertical cylindrical hole 15 made in the float 14.

 Thus, the presence of the float 14 in the device 1 allows you to place its movable part 6 exactly on the surface of the selected section of the ice field 2, within which the ice must be destroyed, and due to the fact that the round vertical cylindrical hole 15 in the float 14 is guide, position the movable part 6 of the device 1 perpendicular to the surface of the ice field 2.

 Due to the fact that the vertical casing 8 of the movable part 6 of the device 1 has a cylindrical shape with a diameter corresponding to the diameter of the round vertical cylindrical hole 15 in the float 14, it is possible to longitudinally reciprocate the movable part 6 of the device 1 relative to its float 14.

 Next, the movable part 6 is removed and the device 1 is turned on. The vibration of the vibratory hammer 9 during operation of the device 1 is transmitted to its entire movable part 6, which during its longitudinal-translational movement relative to the float 14 produces, under the influence of its own weight and the dynamic component caused by vibration, the destruction of ice in this section of the ice field 2.

 In this case, the destruction of ice occurs due to the fact that the maximum pressure transmitted during the vibration of the movable part 6 of the device 1 onto the ice through the lower end of the working body 7 exceeds the value of the ultimate compression resistance of ice.

 When the device 1 is in operation, the safety of its movable part 6 is ensured even when the ice covering the water area is completely destroyed in the area where the device 1 is installed, since the float 14 together with the movable part 6 of the device 1 located inside it will remain afloat .

 The required buoyancy of the float 14 is achieved due to the fact that the float 14 has a lifting force exceeding the weight of the movable part 6 of the device 1 together with the dynamic component that occurs when the vibration hammer 9 vibrates.

 During the operation of the device 1, the possibility of falling out of the movable part 6 of the device 1 from its float 14 is excluded due to the fact that the vertical casing 8 of the movable part 6 is bounded from above by a disk 16 whose diameter exceeds the diameter of the vertical casing 8.

 In addition, to reduce the possible impact of the movable part 6 of the device 1 on its float 14 during operation of the device 1, a shock-absorbing elastic ring 17 is placed below the ring below the protruding part of the disk 16.

 In addition, to prevent the possibility of freezing of the surface of the outer wall of the vertical casing 8 with the wall surface of a round vertical cylindrical hole 15 in the float 14, as well as the lower end of the float 14 with the surface of the ice field 2, and to accelerate the process of ice destruction as a result of its melting, in a selected area ice field 2, inside the working body 7 of the movable part 6 of the device 1 is placed a heater, made, for example, in the form of an electric spiral 18.

 Improving the reliability of the device 1 is achieved due to the fact that the float 14 can be made hollow, it is envisaged that its internal cavity contains a filler 21, consisting of a substance having a lower density compared to the density of water, mainly polystyrene. Thus, even in the event of a possible depressurization of the float 14, it will retain its lifting force.

 After the destruction of ice in a selected area of the ice field 2 using this device 1 will be performed on the entire thickness of the ice, the float 14 with the movable part 6 is again covered up, after which the device 1 is moved using the gantry crane 4 in a predetermined direction and mounted on the surface of the adjacent section of ice field 2 for its destruction already in this section.

 When the device 1 is operating, its movable part 6 and the float 14 may not be detached, but then, to exclude the transmission of vibration to the construction of the portal crane 4, or the cargo rope 22 of the portal crane 4, to which the hook 12 is suspended, must be lowered and in tension condition, or slings 13 and 20, to which respectively the movable part 6 of the device 1 and its float 14 are suspended, should be attached to the hook 12 through vibration damping devices.

 If there are several gantry cranes 4 at the structure 3, device 1, after completion of work on this section of the ice field 2, performed using one of the gantry cranes 4, is moved to the neighboring section, where another gantry crane 4 will be used during the operation of device 1.

 The use of mobile cranes, including gantry cranes 4, to move the device 1 is advisable in cases where ice destruction should be carried out at structures 3, which have a large length in plan.

 In the case of using the device 1 for breaking ice around separate structures 3, for example, drilling platforms, bollards, etc., the movement of the device 1 around them can be carried out using stationary cranes located on the structures 3. In this case, device 1 can also move on a tow rope directly over the surface of the ice field 2 in a predetermined direction from one area where the ice should be destroyed, to another with the help of a suitable truck, for example Tractor-border, also equipped with a cargo boom 5. However, implementation of the operation is possible only at a certain thickness of ice, ensuring the safety of movement of the ice field 2 crawler tractor type used.

 Work on the destruction of ice using the proposed device 1 should continue until the ice is destroyed over the entire previously designated strip on the ice field 2 at the building 3.

Claims (4)

 1. Device for breaking ice, comprising a vertical casing with an eye in the upper part for attachment to a truck, a vibration hammer installed in the casing and connected by a cable to an electric power source, and a pointed working body attached to the lower part of the casing, characterized in that it is equipped with a float with flat horizontal upper and lower ends and a round vertical cylindrical hole, the casing is made round cylindrical and installed in the hole of the float with the possibility of longitudinal th reciprocating movement, the upper housing portion is formed as a disc diameter larger than the hole of the float, and with a shock-absorbing elastic ring on the lower surface.  2. The device according to claim 1, characterized in that the working body is equipped with a heater installed inside it, made in the form of an electric spiral.  3. The device according to paragraphs. 1 and 2, characterized in that the float is made with eyes for attachment to a truck.  4. The device according to claims 1 to 3, characterized in that the float is made hollow, filled with a substance having a lower density compared to the density of water, mainly polystyrene.

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