RU2169245C2 - Device for ice removal from roof eaves of buildings and structures - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: device is provided with rods spring-loaded to oppose mechanical pulses; on one side rods are joined to elastic member made in the form of linear waveguide mechanically joined to roof eave, on other side rod is joined to source of mechanical pulses installed on fastening assembly. Introduction of spring-loaded rods has made it possible to concentrate force pulse coming from source of its disturbance to linear waveguide thereby increasing initial force disturbance amplitude; discrimination of this waveguide from roof eave allows for propagation of forced elastic vibration due to this force disturbance along linear waveguide over greater length compared with prototype. EFFECT: improved efficiency of deicing roof eaves. 7 cl, 3 dwg

Description

 The invention relates to the field of technology, which helps to remove ice or icicles from the eaves of the roofs of various buildings and structures. This area can be expanded in the direction of using this invention to remove ice from the planes and elements of aircraft subjected to this phenomenon during flight, antenna devices and other similar devices subject to icing.

 A device is known for removing ice from the eaves of roofs of buildings and structures, including a movable rigid element located along the eaves for striking ice [1].

 A disadvantage of the known device is the low efficiency of the device due to icing of the device itself moving the rigid element along the ledge, and, in addition, its use for high-rise buildings is practically excluded.

 The closest in technical essence is a device for removing ice from the eaves of roofs of buildings and structures, including a source of mechanical impulses with a node for its attachment to a building or structure and an elastic element located along the eaves of the roof, connected with a source of mechanical impulses [2].

 The reason that impedes the achievement of the required technical result is the low efficiency of the action of the elastic element on ice due to the rigid fastening of the latter to the eaves, as a result of which the excited vibrations in the elastic element damp in the nearest impact zone of the source of mechanical impulses. In addition, the design of the mount, also installed on the roof cornice, dampens mechanical impulses from the source, which further reduces the efficiency of ice removal.

 The basis of the invention is the task of achieving a technical result by increasing the efficiency of the device for removing ice from the eaves of roofs of buildings and structures, which is solved by introducing in the opposite direction spring loaded mechanical pulses with rods, on the one hand, connected with an elastic element made in the form of a linear waveguide, mechanically decoupled from the eaves of the roof, and on the other hand, a source of mechanical impulses mounted on the mount.

 The introduction of spring-loaded rods made it possible to concentrate the force impulse from the source of its perturbation to a linear waveguide, thereby increasing the initial amplitude of the force perturbation in it, and the decoupling of this waveguide from the eaves of the roof allows the forced elastic vibrations from this force perturbation along the linear waveguide to be significantly longer than the known device [2].

 In addition, the linear waveguide is made in the form of any metal profile, the cross section of which provides rigidity along the permissible deflection along the length between the fasteners of two adjacent rods under ice-loaded condition.

 The indicated design feature of a linear waveguide allows for a stable propagation of elastic vibrations over the calculated length of this waveguide.

 Moreover, the size of the mechanical isolation gap between the roof cornice and the elastic element should be greater than the amplitude of the excited oscillations of the linear waveguide from the source of mechanical pulses, and this waveguide should be located in the zone of intense ice formation at the edge of the cornice.

 The size of the mechanical isolation gap and the location of the linear waveguide at the edge of the cornice allows the elimination of ice, for example, in the form of icicles, at the very root of their formation, while eliminating the risk of the vibrating surface of the waveguide coming into contact with the cornice.

 It is reasonable that the mount is mounted on the wall of a building or structure from the outside or inside.

 This installation of the mounting unit increases the rigidity of the entire system in the direction of recoil during mechanical impulses, thereby increasing the amplitude of the impact on the linear waveguide.

 It is also reasonable that the mount is made in the form of a pipe, coaxial to the rod, rigidly fixed in the wall of the building and provided with a cavity on the opposite side for mounting the linear waveguide for installing the source of mechanical pulses between the spring-loaded rod and the stop fixed on the pipe.

 Such a technical solution will improve the comfort of maintenance, and it is also possible to reinstall the pulse sources from one cavity to another, thereby significantly increasing the length of the processed cornice from one device. In addition, it becomes possible to process many buildings and structures from one device.

 Another technical solution is that the source of mechanical pulses is made in the form of a flat eddy current coil and is equipped with a pulse current generator electrically connected to the coil, and an additional plate made of high conductivity material is installed between the coil and the rod.

 Such a design of a source of mechanical pulses will make it possible to produce mechanical pulses lasting from about a dozen fractions to several microseconds, which, at low energy costs for producing a pulse, will allow developing a high impact power along a linear waveguide.

 And finally, between the eddy current coil and the rod there is an additional eddy current coil electrically connected to the first coil.

 This technical solution will increase the efficiency of the transition of electromagnetic processes into mechanical energy.

 Ultimately, the technical result of the implementation of the invention in comparison with the prototype will significantly improve the overall performance of the device as a whole, directly related to increasing the efficiency of removing ice from the eaves. Moreover, the device can operate from various types of sources of mechanical impulses, including magnetic pulse systems, electromagnets, vibrators, mechanical, pneumatic, powder and other types of batteries, and it is even possible to use manual mechanical shocks. Of course, in each case, economic feasibility, efficiency and productivity of cleaning roof eaves from ice should be compared.

 In FIG. 1 shows in longitudinal section a device for removing ice from the eaves of roofs of buildings and structures in the execution of the installation of the mount on the inner (attic) side of the wall.

 In FIG. 2 - the same in the execution of the installation of the mount on the outside of the wall.

 In FIG. 3 is a view A of FIG. 1 and FIG. 2.

A device for removing ice from the eaves of roofs of buildings and structures contains a source of mechanical impulses 1 connected through a cable 2 to a power supply 3 and installed in a cavity 4 of a fastener 5, which is rigidly fixed to the wall 6 of a building or structure, an elastic element made in the form of a linear a waveguide 7 located along the eaves of the roof 8, as well as rods 9, which have springs 10, compressing these rods through the plate 11 to the source of mechanical pulses 1. The rods 9 from the other end are rigidly or pivotally connected to the linear waveguide 7, Making a metal in the form of any profile, such as in FIG. 1 in the form of a corner, and in FIG. 2 - pipes, but with the condition that the rigidity of the deflection is permissible at a length l ₁ and l ₂ between the fasteners of two adjacent rods 9, and the waveguide 7 is mechanically decoupled from the roof eaves through a gap δ equal to a certain value larger than the amplitude of the excited oscillations and at the same time, it is located in the zone of intense ice formation 12. The attachment unit 5 is rigidly mounted with studs 13 on the wall of the building 6 from the outside (Fig. 1) or inside (Fig. 2) side, and in addition, it is equipped with a pipe 14 in which it is located with the ability to move the rod 9 , and the pipe itself is fixed either inside the wall, from the outside, with the help of the flange 15, and from the inside - with the help of the mount 5.

 In addition, the power supply 3 can be made in the form of a pulse current generator, the source of mechanical pulses 1 is a flat eddy current coil, and the plate 11 is made of electrically conductive material or in the form of a second flat coil electrically connected to the first.

 Upon reaching the critical value of icing, which is set for each individual case, the power supply 3 is turned on, and if it is made in the form of a pulse current generator, then electric energy is accumulated in it and when it reaches the set level, it is supplied through the cable 2 to the source for a short period of time mechanical pulses in the form of a coil of eddy currents, in which electrical energy is converted into a magnetic field interacting with a plate 11 having high electrical conductivity, or with a second cat for example, connected in series with the first one, and as a result, the plate or additional coil 11 is sharply repelled from the source of mechanical impulses (main coil) 1. In turn, the plate or additional coil drives the spring-loaded rod 9, which strikes the linear waveguide 7, exciting forced elastic vibrations in the last element. These vibrations, extending over the entire length of the waveguide, shake off the ice both from the waveguide itself and from the eaves of the roof 8. After performing useful work, the rod 9 returns to its original position due to the spring 10.

 Bibliographic data.

 1. Antipenko A.A. RF patent N 2096567, cl. E 04 D 13/076, 03/13/96

 2. Levin I.E. RF patent N 1638285, cl. E 04 D 13/06, 02.24.89

Claims (7)

 1. A device for removing ice from the eaves of roofs of buildings and structures, including a source of mechanical impulses with a mount on the building or structure and an elastic element located along the eaves of the roof connected with a source of mechanical impulses, characterized in that it is additionally spring loaded in the opposite direction the direction of the action of mechanical pulses by rods, on the one hand connected with an elastic element made in the form of a linear waveguide, mechanically decoupled from the eaves of the roof, and on the other hand Orons - with a source of mechanical impulses mounted on the mount.  2. The device according to claim 1, characterized in that the linear waveguide is made in the form of any metal profile, the cross section of which provides stiffness along the permissible deflection along the length between the fasteners of two adjacent rods under ice-loaded condition.  3. The device according to claim 1, characterized in that the mechanical isolation gap between the roof cornice and the elastic element should be greater than the amplitude of the excited oscillations of the linear waveguide from the source of mechanical pulses, and the specified waveguide should be located in the area of intense ice formation at the edge of the cornice.  4. The device according to claim 1, characterized in that the mount is mounted on the wall of a building or structure from the outside or inside.  5. The device according to claim 1, characterized in that the mount is made in the form of a pipe, coaxial with the rod, rigidly fixed in the wall of the building and provided with a cavity on the opposite side of the linear waveguide for mounting the source of mechanical pulses between the spring-loaded rod and the stop fixed on the pipe.  6. The device according to claim 1, characterized in that the source of mechanical pulses is made in the form of a flat eddy current coil and is equipped with a pulse current generator electrically connected to the coil, and a plate made of high conductivity material is installed between the eddy current coil and the rod.  7. The device according to any one of claims 1 to 6, characterized in that between the eddy current coil and the rod there is an additional eddy current coil electrically connected to the main coil.

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