RU2137408C1 - Vibration-protecting mitten - Google Patents

Abstract

FIELD: appliances for protecting hands from vibration generated by vibratory equipment and hand-held tools, such as that used in wood-working industry and forestry. SUBSTANCE: mitten has body defined by rear and palm portions, finger stall for thumb or for thumb and indicating finger, inner layer and vibration-protective insert made from foamed polyurethane and arranged between body and inner layer at side adjoining palm. Structure of foamed polyurethane has spherical gas cells of different diameter which are isolated one from the other and nonuniformly distributed through thickness of insert. Insert has row of parallel horizontal tubular pockets filled with foamed polyurethane, which is cut into pieces with sizes of faces making 0.2-1.0 of thickness of insert tubular pocket. EFFECT: simplified construction and increased efficiency in reducing vibration level within wide range of frequencies. 2 dwg

Description

 The invention relates to personal protective equipment against vibrations generated by vibro hazardous equipment and hand tools. And basically it can be used in the forestry and woodworking industries when the operator works with gasoline-powered saws.

 A gasoline-powered saw is a powerful source of dynamic loads, which, depending on the operating mode, are fully or partially perceived by the operator. In this regard, one of the most important tasks when creating a vibration-proof gauntlet is to minimize the level of vibration in the palm of the hand, which perceives the main influx of vibrational energy when the operator is working with the saw.

 The difficulty in solving this problem lies in the fact that, depending on the operating mode (idling on the bucking, felling), the operator’s hands are affected by vibration loads in a wide frequency range of 30 - 1000 Hz.

 In the countries of Scandinavia (Finland, Sweden, Norway), where the forestry and woodworking industries are the most developed, protective gloves are widely used by operators when working with gasoline saws (see, for example, the Kladeroch Skyadsutusting for skograrbete work clothes catalog, p. 19 - 20). According to this catalog, Nordfor protective gloves are known. They are made of durable and soft calfskin. They have a shape that excludes the formation of wrinkles (wrinkles) on the surface of the palm of the hand, designed to protect against injuries and convenience when grabbing a chainsaw. Saw protection elements are located in the left mitten on the back side. As follows from the design description of the mitten, they are not intended to protect the operator’s hands from vibration, but protect them only from mechanical injuries.

 Known vibration protective gloves related to personal protective equipment against vibration exposure generated by vibration-hazardous tools, in particular chipping hammers (see application of the USSR AS 901646, class A 41 D 13/08 for 1982). In this design, the gloves are vibration-proof liner made in the form of a series of parallel horizontal tubes filled with air.

 The main disadvantages of this design of the mitten are: the complexity of the design, the vulnerability of the inflatable vibration-proof liner from mechanical damage, the limited range of application of the mitts at the operating vibration frequencies.

 MV anti-vibration gloves are also known (GOST 12.4.010-75, TO 78-349-75), widely used in industry for protecting the operator’s hands when working with pneumatic chisels, rammers, jack hammers, drills and other types of hand tools (see book "Personal protective equipment for workers in production." Directory-directory, M., Profizdat, 1988, p. 97).

 They are made from cotton fabrics. The palms of the mittens are reinforced with a textin lining and a foam cushioning pad. The use of foam rubber as a vibration-proof liner can significantly simplify the design of the mittens and make them more reliable in operation. Foam is a polyurethane foam with open, interconnected gas cells (pores).

 Vibration damping is carried out in the insert itself due to internal friction in the polymer base (matrix) of the viscoelastic material of the foam insert. Since the main volume of the liner is occupied by interconnected gas cells (pores), the polymer base itself (its mass) is not enough to effectively damp the vibration. As noted in the book by M.L. Brainina, L. P. Klimova et al. "Personal Protective Equipment for Hands" (M., Profizdat, 1990, p. 22), anti-vibration gloves produced by industry (GOST 12.4.010-75, MOT 78-349-75) with foam padding are ineffective. Effective damping of vibration by such mittens is carried out only at a strictly defined resonant frequency of the liner, determined by the physicomechanical characteristics of the foam matrix.

 Also known vibration-proof mitten (see RF application N 95110630/12, CL A 41 D 13/08, 07/10/97), adopted by the authors for the prototype.

 It includes a body in the form of the back and palm parts, finger and thumb and thumb fingers, an inner lining and a vibration-proof polyurethane foam liner located between the body and the inner lining on the palm side and having insulated unevenly distributed across the thickness of the liner in the thickness of the liner gas cells of a spherical shape of different diameters from each other, while the vibration-proof liner is made in the form of an integral structure.

 Vibration damping is carried out in the liner itself due to internal friction in the polymer base (matrix) of the viscoelastic material of the liner and due to the work of deformation of the shells of the internal gas cells when exposed to a vibration load. Thus, in this design of the mitt, two mechanisms of dispersion of vibrational energy supplied to the control handles of the saw are combined. Gas cells isolated from each other that are unevenly distributed over the thickness of the liner have different diameters that determine their different corresponding resonant frequencies. As a result of this, an effective reduction in the level of vibration in the mitt is provided over a wide frequency range.

The main disadvantage of this mitten design is that its effectiveness substantially depends on the internal structure of the liner material, namely the ratio of the total volume of gas cells V _g to the total volume of the liner V _c . In accordance with the subject of the invention, in the liner of this mitten, the total volume of gas cells should be strictly 0.4 - 0.6 of the total volume of the liner.

When the total volume of gas V _g cells less than 0.4 V from the total volume of the liner _in slumping vibration-absorbing properties of gloves, since a small amount of gas cells leads to a reduction in the diffusion of the vibrational energy through the work of deformation of the shells from the effects of exposure. In this case, vibration absorption is carried out only due to internal friction in the polymer base (matrix) of the viscoelastic material of the liner. With a total volume of gas cells of more than 0.6 of the total volume of the liner of the handle, the viscoelastic properties of the polymer base (matrix) of the handle significantly deteriorate. Reducing the viscosity properties of the polymer matrix material of the handle due to a general decrease in its weight at V _d> 0.6 V _in, resulting in a decrease in magnitude of vibration energy dissipation by internal friction in the polymer matrix of the liner material.

 It is extremely difficult to achieve a strict ratio of the volume of gas cells and the matrix of the polyurethane foam insert in practice. Each time when pouring vibration-insulating liners, it is required to produce an advanced sample and examine it for gas filling. This significantly complicates the technology of manufacturing mittens, which is unacceptable in the conditions of their mass production.

 The second disadvantage of the mitten, adopted by the authors for the prototype, is the large bending stiffness of the vibration-proof liner, made in the form of an integral structure. The operator performs additional mechanical work when bending his fingers to the palm of his hand to hit the vibration tool, as a result of which his hands quickly get tired.

 The aim of the present invention is to remedy these drawbacks and create a vibration-proof mitten from a polyurethane foam liner that does not have a strict ratio between the volume of gas cells and the material matrix, but more effectively dampens vibration in a wide frequency range (30-1000 Hz) at high loads (pressing force on the handles tool management up to 150 N). At the same time, the mittens have practically zero bending stiffness of the vibration-proof insert.

 The essence of the invention lies in the fact that the vibration protective glove includes a body in the form of the back and palm parts of the finger or thumb and thumb fingers, the inner lining and the vibration protection foam insert, located between the body and the inner lining on the palm side and having in polyurethane foam, gas cells of a spherical shape of different diameters, unevenly distributed over the thickness of the liner, different from each other, characterized in that the vibration-proof liner is full in the form of a series of parallel horizontal tube-pockets filled with polyurethane foam, cut into pieces with dimensions along the sides of 0.2 - 1.0 of the thickness of the liner tubes.

 In FIG. 1, 2 shows a general view of the mitten. The gauntlet includes a housing 1, a vibration-proof liner 2, made of horizontal tubes 3 filled with cut pieces of polyurethane foam 4, napalka on the thumb 5, the inner lining 6.

 When sawing, the main flow of vibrational energy comes from the saw apparatus of the chainsaw and is transmitted through the support frame to the control handles.

 The work of the gauntlet is as follows. When the operator is working, he in mittens grabs the handles of the chainsaw with a certain force (up to 150 N) to hold and control the chainsaw, as a result of which the deformation of the sleeve insert occurs.

 The vibration damping is carried out in the liner itself due to internal friction in the polymer base (matrix) of the viscoelastic polyurethane foam material and due to the work of deformation of the shells of the internal gas cells under the influence of vibration load. The gas cells isolated from each other, unevenly distributed over the thickness in the sliced pieces of the polyurethane foam liner, have different diameters, which determine their different corresponding resonant frequencies. As a result of this, an effective reduction of the vibration level in the mitt is provided in a wide frequency range. Thus, as in the prototype, in the proposed design of the gauntlet, these two types of mechanisms for dispersing vibrational energy are preserved, but an additional mechanism for combating vibration is added.

 This is an additional vibration damping due to mechanical friction between the surfaces of the cut pieces of polyurethane foam in the tube-pockets of the liner when exposed to vibration load.

 It should be noted that since the packing of sliced pieces of polyurethane foam in the tube-pockets of the liner is carried out arbitrarily, the surfaces of the chopped pieces of polyurethane foam rubbing together have different areas. This provides an effective damping of vibration in a wide range of operating frequencies (30-1000 Hz).

 On the basis of numerous experimental data (sawing at the stand in idle, bucking and felling with measuring vibration levels on the palms of the operator’s hands), the authors found that the aspect ratio of the cut pieces of polyurethane foam from the thickness of the filled tube-pocket liner.

 When the face size of the cut pieces of polyurethane foam is less than 0.2 of the thickness of the filled tube-pocket of the liner, the vibration damping efficiency is sharply reduced by cutting a large number of internal gas cells of the polyurethane foam liner. This leads to a sharp decrease in the total number of isolated gas cells from each other and, as a consequence, to a decrease in the amount of dispersion of vibrational energy due to the work of deformation of the shells from the effects of vibrational loads.

 When the size of the face of the cut pieces of polyurethane foam is more than 1.0 of the thickness of the filled tube-pocket of the liner, the vibration damping efficiency is also reduced. In this case, when the dimensions of the cut pieces of polyurethane foam exceed the thickness of the tube-pockets of the liner, they are in a pre-compressed state. The shells of the gas cells partially close, the total work of deforming them decreases from exposure to vibrational loads, which, as in the first case, leads to an increase in the level of vibration on the hands of the operator.

 At present, bench and field tests of the proposed vibration-protective mittens have been carried out, which have shown high damping efficiency in the operating frequency range of 30-1000 Hz.

 To improve the controllability of the saw apparatus, the manufacture of mittens according to the invention with two filings on the thumb and forefinger of the operator’s hands is allowed.

Claims (1)

 Vibro-protective mitten, which includes a body in the form of the back and palms, finger or thumb and index finger inserts, an inner lining and a vibration-proof polyurethane foam liner located between the body and the inner lining on the palm side and having a polyurethane foam unevenly distributed over the liner thickness isolated from each other gas cells of a spherical shape of different diameters, characterized in that the vibration-proof liner is made in the form of a series of parallel horizontal tubes - pockets filled with polyurethane foam, cut into pieces with dimensions along the sides of 0.2-1.0 of the thickness of the liner tubes.

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