RU2648103C1 - Operator's cabin, working in conditions of high dust content and high noise levels - Google Patents

Abstract

FIELD: means of protection.

SUBSTANCE: invention relates to safe instruments of labor, in particular during operators activities in emergency situations, accompanied by increased levels of dust and noise. Technical result is achieved by the fact that in the operator's cabin, working under conditions of high dust content and high noise levels, containing a base, a frame, life support equipment, window and door openings and enclosures in the form of acoustic panels, the base is installed on at least three pneumatic vibration isolators, to which the carcass of the cabin rigidly fastened in the form of acoustic noise-absorbing panels, as well as a ceiling part with lamps, a rear wall located in a plane parallel to the plane of the front wall, and four side walls, where one has a door, and the cabin is sealed and equipped with a life support system in the form of an artificial microclimate system with a control panel, and also a workplace that includes a work table, a chair with vibration isolators in the form of elastomer plates attached to the legs of the chair, and a hanger for changing clothes, the life support system is made in the form of an artificial microclimate system with a control panel, the acoustic noise-absorbing panel is made in the form of a sound-absorbing structure consisting of a rigid and perforated walls, between them there is a multi-layer sound-absorbing element made in the form of five layers, two of them, adjacent to the walls, are sound-absorbing layers of materials of different density, and three central layers are combined, besides the sound-absorbing member is lined on its entire surface with an acoustically transparent material, and each of the pneumatic vibration isolators where the base of the cabin is installed is made by two-chamber with at least three working chambers in the form of rubber-cord shells, each of them is connected by means of an inter-chamber choke with a damper chamber located in the base of the cabin, in accordance with the invention, the damper chamber is in the form of a toroidal cavity of rectangular cross-section having a common bottom base and bounded from above by an upper round base, where there is an inter-chamber choke connecting the cavities of the rubber-cord shell and the damper chamber, the upper round base of the toroidal cavity of the rectangular section serving as the lower support surface of the rubber-cored shell, and the upper supporting surface of the rubber-cord shell is the support disc, where the base of the operator's cabin is supported through the vibration damping gasket, and between the lower base of the toroidal cavity of a rectangular section and its upper round base, where a rubber-cord shell is fixed by its lower support surface, a gap is connected the cavity of the working and damper chambers of the pneumatic vibration isolator through the chamber choke.

EFFECT: technical result is to increase the efficiency of the operator by reducing the levels of dust and noise.

3 cl, 9 dwg

Description

The invention relates to safe means of work, in particular when operators work in emergency situations, accompanied by increased levels of dust and noise.

The closest technical solution to the technical nature and the achieved result is an acoustic cabin according to the patent of the Russian Federation No. 138708 [prototype], containing a base, frame, life support equipment, window and doorways and fences in the form of acoustic panels.

The disadvantage of the technical solution adopted as a prototype is the relatively low efficiency of sound attenuation due to the relatively low coefficient of sound absorption.

The technical result is an increase in operator efficiency by reducing dust and noise levels.

This is achieved by the fact that in the operator’s cabin, operating in conditions of increased dust and high noise levels, containing a base, frame, life support equipment, window and door openings and fences in the form of acoustic panels, the base is installed on at least three pneumatic vibration isolators made in a rubber-cord shell, and the cabin frame is rigidly fixed to it, made in the form of a polygonal prism with ribs perpendicular to the base of the cabin, and consisting of a front wall, with glazing, made of a noise-reflecting translucent panel, a ceiling part with lamps, a rear wall located in a plane parallel to the plane of the front wall, and four side walls, in one of which a door is installed, while the area of the rear wall is at least 2 times the area of the front wall and the side walls adjacent to the front wall are made inclined with respect to it and with glazing, and adjacent to the rear wall are perpendicular to it, and the cabin is sealed and equipped with a life-saving system maintenance in the form of an artificial microclimate system with a control panel, as well as a workplace that includes a work desk, a chair with vibration isolators in the form of elastomer plates attached to the legs of the chair, and a hanger for interchangeable clothes.

In FIG. 1 shows a general view of the operator’s cab operating in conditions of increased dust and high noise levels, FIG. 2 is a general view of an acoustic noise absorbing panel; in FIG. 3 is a general view of an acoustic noise-reflecting translucent panel of a glazing of a cabin; FIG. 4 is a general view of the cassette air conditioner, in FIG. 5 is a general view of the operator’s chair; FIG. 6 is a characteristic of an elastomer of the type “vibroflex EP / 25A, in FIG. 7 is a general view of elastomeric vibration damping plates of the “VEP” type; FIG. 8 is an embodiment of an acoustic sound-absorbing panel for cladding an operator’s cabin; FIG. 9 is a variant of a pneumatic vibration isolator 5, on which a base 1 of a cabin is mounted.

The operator’s cab operating in conditions of increased dust content and high noise levels contains a base 1 (Fig. 1) mounted on at least three pneumatic vibration isolators 5 made in the form of a rubber-cord casing. The cab frame is rigidly attached to the base, made in the form of a polygonal prism with ribs perpendicular to the base of the cab 1, and consisting of a front wall 2, with a glazing 4 made of a reflective translucent panel, ceiling part 3 with lights 12, and a rear wall 14 located in a plane parallel to the plane of the front wall 2 and four side walls, one of which has a door 11. The area of the rear wall 14 is at least 2 times larger than the area of the front wall 2, and the side walls adjacent front wall, are inclined with respect thereto and with glazing and adjoining the rear wall - perpendicular thereto.

The cabin is sealed and equipped with a life support system in the form of an artificial microclimate system 13 with a control panel 9, as well as a workstation including a work desk 6, chair 7 with vibration isolators 8 in the form of plates made of elastomer attached to the legs of the chair, and a hanger for removable clothes 10.

The cabin frame is made in the form of acoustic noise-absorbing panels (Fig. 2), the frame of which is made in the form of a parallelepiped formed by the front 15 and rear 16 panel walls, each of which has a U-shape, with slotted perforations 17 and 18 on the front wall, the perforation coefficient of which is taken to be equal to or more than 0.25, and the panel walls are fixed between themselves by vibration damping covers 19, and basaltic mineral wool boards are used as sound-absorbing material 20 of the sound-absorbing element Rockwool type ove. For the rigidity of the carcass, side ribs 21 are provided on the walls 15 and 16. As a sound-absorbing material, layers of mineral wool of the URSA type, or basalt wool of the P-75 type, or glass wool coated with glass wool, or foamed polymer, for example polyethylene or polypropylene, can be used. moreover, the sound-absorbing element over its entire surface is lined with an acoustically transparent material, for example, fiberglass type EZ-100 or polymer type "Poviden." As a sound-absorbing material of an acoustic sound-absorbing panel, plates based on aluminum-containing alloys are used, followed by filling them with titanium hydride or air with a density in the range of 0.5 ... 0.9 kg / m ³ with the following strength properties: compressive strength in the range of 5 ... 10 MPa , bending strength within 10 ... 20 MPa, and the front and rear walls of the frame are made of stainless steel or galvanized sheet with a thickness of 0.7 mm with a protective and decorative polymer coating such as “Pural” with a thickness of 50 μm or “Polyester” of thickness another 25 microns, or an aluminum sheet with a thickness of 1.0 mm and a coating thickness of 25 microns, and the ratio of the height h of the frame to its width b is in the optimal ratio of values: h / b = 1.0 ... 2.0; and the ratio of the thickness s 'of the frame assembly to its width b is in the optimal ratio of values: s' / b = 0.1 ... 0.15; and the ratio of the thickness s of the sound-absorbing element to the thickness s 'of the frame assembly is in the optimal ratio of values: s / s' = 0.4 ... 1.0, and the vibration damping covers fixing the panel walls are made of elastomer, polyurethane foam or polyethylene foam, wood fiber, particleboard material, or gypsum-asphalt board, or elastic sheet vibration-absorbing material with an internal loss factor of at least 0.2, or a composite material, or plastic compound such as "Agate", "Anti-Vibrate", "Shvim".

The glazing of the cabin is made in the form of a reflective translucent panel (Fig. 3), made in the form of a polygon, for example, a rectangle formed by a U-shaped ribs 22-25 made of vibration damping material, and a panel of a solid sheet 26 extruded is used as a reflective translucent element polycarbonate plastic, and the ratio of the length of the rectangle to its height is in the range from 2 to 3, and the ratio of the thickness of the continuous sheet of extruded polycarbonate plastic to its the height is in the optimal range of values: 0.006 ... 0.008.2, and as a noise-reflecting translucent element, a panel of cellular sheet 27 of extruded polycarbonate plastic is used with the ratio of the length of the rectangle to its height being in the optimal ratio of values: 2.0 ... 3.0, and the ratio of thickness the cellular sheet of extruded polycarbonate plastic to its height is in the optimal range of values: 0.016 ... 0.02, and the cell 28 of the cellular sheet of extruded polycarbonate plastic is made in the form of a side the surfaces of polyhedral rectangular prisms, for example, square or rectangular sections, faces 29 or ribs of which are rigidly connected to each other and to continuous sheets of extruded polycarbonate plastic located on both sides of the cells.

The cassette air conditioner (Fig. 4) is mounted behind a suspended ceiling, which allows to save room space, it fits most organically into any cabin interior, since only the decorative panel of the indoor unit is visible, and the air from the cassette model of the air conditioner spreads along the ceiling in four uniform streams . The most effective can be applied cassette conditioner company General Climate type GC / GU-4C18HR.

The operator’s chair (Fig. 5) is made of metal and provides a high degree of comfort due to the ergonomic design, for example, metal chairs "Argumet" with dimensions, mm: overall height 1000; seat height 450; width 420; depth 480. The frame of the chair is made of a round pipe with a diameter of 22 mm; the lifting unit is made in the form of a gas lift (stroke - 130 mm); seat base: metal plate 3 mm, + plywood 8 mm, + foam layer 20 mm + leather / deputy (black color); back base: plywood 8 mm, + foam layer 20 mm + leather / deputy (black color); lower base of the chair: plastic five-beam; carcass coating: polymer powder; frame color RAL 5004 (black); load up to 100 kg.

As an elastomer attached to the legs of the chair, can be used "Vibroflex EP / 25 A" (Fig. 6), which is designed for a load of 25 kg The graph shows that it is most effective precisely at such a load. Acoustic material of a new generation is also effective - VEP type elastomeric vibration damping plates (TU 2534-001-32461352-2002) (Fig. 7), which provide a reduction of vibration levels from mechanisms and machines to 85%, in the range from 2 to 10000 Hz , and carry out the reduction of air, structural and impact noise by 17 ÷ 22 dB. VEP vibration damping plates are produced in the form of rolled material with a thickness of 4 mm and a width of 1200 mm, as well as plates of 700 × 700 mm with a thickness of 10 mm and 20 mm. The temperature range of the operation of the WEP is from minus 40 to plus 120 ° C. The service life of VEP plates is 50 years or more. Vibration damping plates undergo regular certification tests at the Research Institute of Construction Equipment.

Technical details

Elongation at break,% - at least 300; Shore A hardness, Unit Shore A - 45-75; rebound elasticity,% - no more than 15; dynamic modulus of elasticity (at a load of 5000 N / sq.), MPa - 14-38; impact noise insulation improvement index, dB - 17-22; frequency range of operation, Hz - 2-10000; operating temperature range, ° С - -40 ... + 120; conditional tensile strength, MPa - not less than 8.0.

A variant of the acoustic sound-absorbing panel for cladding the operator's cabin, made in the form of a sound-absorbing structure (Fig. 8).

The sound-absorbing structure (Fig. 8) is made in the form of a smooth rigid wall 30 and a perforated wall 36, between which there is a multilayer sound-absorbing element made in the form of five layers, two of which adjacent to the walls 30 and 36 are sound-absorbing layers 31 and 35 of materials of different densities, and the three central layers 32, 33, 34 are combined, and the axial layer 33 is made sound-absorbing, and two symmetrically located and adjacent layers 32 and 34 are made of sound-reflecting material of a complex profile I, composed of uniformly distributed hollow tetrahedrons, permitting the reflection of falling in all directions the sound waves. The perforated wall 36 has the following perforation parameters: diameter of the holes is 3 ÷ 7 mm, the percentage of perforation is 10% ÷ 15%, and the shape of the holes can be made in the form of holes of a round, triangular, square, rectangular or diamond-shaped profile, while in the case of non-circular holes as the conditional diameter should be considered the maximum diameter of the circle inscribed in the polygon.

Each of the walls 30 and 36 can be made of structural materials, with a layer of soft vibration-damping material, for example, VD-17 mastic or “Gerlen-D” type material, applied on one or two sides of the material, and the ratio between the thicknesses of the material and vibration-damping coating lies in the optimal range of values: 1 / (2.5 ... 3.5).

Each of the walls 30 and 36 can be made of stainless steel or galvanized sheet with a thickness of 0.7 mm with a protective and decorative polymer coating such as Pural 50 μm thick or Polyester 25 μm thick, or an aluminum sheet 1.0 mm thick and coating thickness 25 microns. The perforation coefficient of perforated sheets is taken to be equal to or more than 0.25.

Each of the walls 30 and 36 can be made of solid, decorative vibration damping materials, such as plastic compounds such as Agate, Anti-Vibrate, Shvim, with the inner surface of the perforated surface facing the sound-absorbing structure, lined with an acoustically transparent material, such as fiberglass type EZ-100 or a polymer of the “poviden” type, or nonwoven materials, for example, “lutrasil”.

As the material of the sound-reflecting layers 32 and 34, a material based on aluminum-containing alloys can be used, followed by filling them with titanium hydride or air with a density in the range of 0.5 ... 0.9 kg / m ³ with the following strength properties: compressive strength in the range of 5 ... 10 MPa, bending strength within 10 ... 20 MPa, for example foam aluminum, or soundproofing boards based on glass staple fiber of the “Shumostop” type with a material density of 60 ÷ 80 kg / m ^{3 were used} .

As sound-absorbing material of layers 31, 33 and 35, rockwool-type mineral wool or URSA-type mineral wool, or P-75-type basalt wool, or glass wool with glass fiber lining, or foamed polymer, for example, can be used. polyethylene or polypropylene. Moreover, the sound-absorbing material over its entire surface is lined with an acoustically transparent material, for example, EZ-100 fiberglass or a “visible” polymer, or the surface of the fibrous sound absorbers is treated with special porous paints that allow air to pass through (for example, Acutex T) or coated with breathable fabrics or non-woven materials, e.g. Lutrasil. In addition, as a sound-absorbing material of layers 2 and 4, a porous sound-absorbing material can be used, for example, foam aluminum or cermets, or a stone shell with a degree of porosity that is in the range of optimal values: 30–45%, or metal foam, or a compressed material crumbs from solid vibration-damping materials, such as elastomer, polyurethane, or plastic compound such as Agate, Anti-Vibrate, Shvim, and the size of the fractions of the crumb lies in the optimal range of values: 0.3 ... 2.5 mm, and can also porous mineral piece materials, for example pumice, vermiculite, kaolin, slag with cement or other binder, or synthetic fibers, or the surface of the fibrous sound absorbers are treated with special porous airborne paints such as Acutex T or coated with breathable fabrics or non-woven materials e.g. Lutrasil.

The operator’s cab, working in conditions of increased dust and high noise levels, operates as follows.

Sound energy from the equipment located in the room where the cabin is installed, passing through the perforated wall 15, enters the layers of sound-absorbing material 20 (which can be either soft, for example from basalt or glass fiber, or hard, for example, like an acigran and t .P.). The transition of sound energy into thermal energy (dissipation, energy dissipation) occurs in the pores of a sound absorber, which are the Helmholtz resonator model, where energy losses occur due to friction of the mass of air in the resonator neck oscillating with the frequency of excitation on the neck wall, which has the form of a branched sound absorber pore network. The perforation coefficient of the perforated wall 15 is taken to be equal to or more than 0.25. To prevent the soft sound absorber from spilling out, a fiberglass fabric is provided, for example, type EZ-100, located between the sound absorber and the perforated wall 15. Dusty air from the equipment located in the room where the cabin is installed, passing through the life support system 13, acquires properties that meet sanitary and hygienic requirements for workplaces.

Sound-absorbing design works as follows.

Sound energy, passing through the perforated wall 36, falls on a layer 35 of soft sound-absorbing material, and then meets in its way layers 34, 33 and 32 of sound-reflecting material of a complex profile, consisting of uniformly distributed hollow tetrahedrons that allow reflecting falling in all directions sound waves, but part of the sound energy passes through layers 32 and 34 of sound-reflecting material, and interacts with the axial layer 33 of sound-absorbing material, where the final dispersion sound energy.

Layers 31 and 35 of soft sound-absorbing material of different densities can be made, for example, of basalt or glass fiber. In fibrous absorbers, the dissipation of the energy of air vibrations and its transformation into heat occurs at several physical levels. Firstly, due to the viscosity of the air, and secondly, due to friction of the air against the fibers, the surface of which is also large. Thirdly, the fibers rub against each other and, finally, energy dissipation occurs due to the friction of the crystals of the fibers themselves. This explains that at medium and high frequencies the sound absorption coefficient of fibrous materials is in the range of 0.4 ... 1.0.

In FIG. 9 shows an embodiment of a pneumatic vibration isolator 5.

It is possible that the pneumatic vibration isolators 5, on which the cab base 1 is mounted, are made of two-chamber with at least three working chambers in the form of rubber-cord shells 37, each of which is connected via an interchamber choke 39 with a damper chamber 38 located in the base of the cab 1.

A variant is possible (Fig. 9), when each of the pneumatic vibration isolators 5, on which the cab base 1 is mounted, is made two-chamber with at least three working chambers in the form of rubber-cord shells 37, each of which is connected via an interchamber choke 39 with a damper chamber 38, located under the base of 1 cabin. The damper chamber 38 is made in the form of a toroidal cavity of rectangular cross-section, having a common lower base 44, and bounded above by an upper circular base 45, in which there is an interchamber choke 39 connecting the cavities of the rubber-cord shell 37 and the damper chamber 38. The upper circular base 45 of the toroidal cavity of rectangular cross section serves as the lower supporting surface of the rubber-cord shell 37, and the upper supporting surface of the rubber-cord shell 37 is the support disk 40, onto which through vibration damping The roclad 41 rests on the base 1 of the operator's cab. Between the lower base 44 of the toroidal cavity of rectangular cross section and its upper circular base 45, on which the rubber cord shell 37 is fixed with its lower supporting surface, a gap 42 is made connecting through the interchamber choke 39 of the cavity of the working and damper chambers of a pneumatic vibration isolator.

It is possible that in the upper part of the rectangular toroidal cavity of the pneumatic vibration isolator 5 (Fig. 9), on which the cab base 1 is mounted, a buffer ring 43 is fixed, which acts as an elastic limiter when depressurizing the cavities of pneumatic vibration isolators 5.

It is possible that in the cavity of the buffer ring 43, which functions as an elastic limiter when depressurizing the cavities of pneumatic vibration isolators 5, there is an additional container made in the form of a toroidal rubber-cord shell 46 connected by three valves 47 to the damper chamber 38, which overlap during depressurization of the cavities of pneumatic vibration isolators 5 cavity rubber-cord shell 46, working offline.

Claims (3)

1. The cabin of the operator, working in conditions of increased dust and high noise levels, containing a base, frame, life support equipment, window and door openings and fences in the form of acoustic panels, the base is installed on at least three pneumatic vibration isolators, to which the cab frame is rigidly fixed made in the form of acoustic sound-absorbing panels, as well as the ceiling part with lights, a rear wall located in a plane parallel to the plane of the front wall, and four side walls ok, in one of which a door is installed, and the cabin is sealed and equipped with a life support system in the form of an artificial microclimate system with a control panel, as well as a workplace including a work desk, a chair with vibration isolators in the form of elastomer plates attached to the legs of the chair , and a hanger for interchangeable clothes, the life support system is made in the form of an artificial microclimate system with a control panel, for example, in the form of a cassette air conditioner from General Climate, an acoustic noise absorption the nel is made in the form of a sound-absorbing structure consisting of a rigid and perforated wall, between which there is a multilayer sound-absorbing element made in the form of five layers, two of which adjacent to the walls are sound-absorbing layers of materials of different densities, and the three central layers are combined, moreover, the axial layer is made sound-absorbing, and two symmetrically arranged adjacent layers are made of sound-reflecting material of a complex profile, consisting of uniformly distributed hollow tetrahedrons, rockwool basalt-based mineral wool slabs are used as sound-absorbing material, and the sound-absorbing element is lined with acoustically transparent material over its entire surface, for example, EZ-100 fiberglass or “see-through” polymer, and each pneumatic vibration isolators, on which the cab base is installed, is made of two-chamber with at least three working chambers in the form of rubber-cord shells, each of which is connected by interchamber choke with a damper chamber located at the base of the cab, characterized in that the damper chamber is made in the form of a toroidal cavity of rectangular cross section, having a common lower base and bounded above by an upper circular base, in which there is an interchamber choke connecting the cavity of the rubber-cord shell and the damper chamber, the upper circular base of the toroidal cavity of rectangular cross section serves as the lower supporting surface of the rubber-cord shell, and the upper supporting surface The rubber-cord casing serves as a support disk, on which the operator’s cab base is supported through a vibration-damping gasket, and between the lower base of the toroidal cavity of rectangular cross section and its upper round base, on which the rubber-cord shell is fixed with its lower supporting surface, a gap is made connecting the working cavity through the interchamber choke and damper chambers of a pneumatic vibration isolator. 2. The operator’s cabin, operating in conditions of increased dust and high noise levels, according to claim 1, characterized in that in the upper part of the toroidal cavity of the rectangular cross section of the pneumatic vibration isolator, on which the cab base is mounted, a buffer ring is fixed that acts as an elastic limiter during depressurization cavities of pneumatic vibration isolators. 3. The operator’s cab, operating in conditions of increased dust and high noise levels, according to claim 1, characterized in that in the cavity of the buffer ring, which functions as an elastic limiter when depressurizing the cavities of pneumatic vibration isolators, there is an additional tank made in the form of a toroidal rubber cord casing, connected by three valves with a damper chamber, which, when depressurized the cavities of pneumatic vibration isolators, overlap the cavity of the rubber-cord shell operating in stand-alone mode by

Images