NO152279B - HOERSELVERNANORDNING - Google Patents

Description

The invention generally relates to hearing protection devices and more particularly to hearing protection devices of the type comprising a spring-type headband with a pair of ear canal contact parts attached to the end portions of the headband.

Hearing protection devices of the type comprising a generally U-shaped spring headband with a pair of inwardly directed ear canal contact parts attached to the end portions of the headband are known as such. Compared to earmuff-type hearing protection devices, such hearing protection devices generally exhibit the advantages of lower weight and lower volume. However, they are often significantly less effective when it comes to dampening sound, which is the main purpose of such hearing protection devices, compared to hearing protection devices of the earmuff type.

British patent document 1355052 relates to a hearing protection arrangement with a headband which is connected at its two opposite ends, e.g. ball-jointed joint, with an ear plug or plug. The distinctive feature of the known hearing protection device is that each earplug is designed in one piece and is provided with a flexible, hollow stem which is provided with transverse ribs and is closed at one of its ends. One of these ends is provided with a fastener to removably engage the headband and to limit movement of the headband along the stem, whereby the headband in use tends to hold each earplug in place in the wearer's ear canal.

The aim of the invention is to provide

bring hearing protection devices of the type comprising a generally U-shaped spring headband and ear canal contact parts attached to the end portions of the headband, these hearing protection devices having improved sound attenuation properties compared to similar known hearing protection devices.

The invention also aims to provide hearing protection devices of the above-mentioned type which are comfortable to use at the same time as they exhibit excellent sound dampening properties, have low noise and low weight and have ear canal contact parts which are self-adaptive to the user's ear canals.

The invention thus relates to a hearing protection device

of the type comprising a generally U-shaped spring headband

which attached to each of its opposite end portions has an inwardly directed ear canal contact portion each of which has a first end portion which can be forced into an ear canal closing relationship by the spring headband, and an opposite second end portion having external dimensions sufficiently small that it will be surrounded by the auricle and is directly connected to an end portion of the headband, the first end part of each of the ear canal contact parts comprising a sealing plug, at least the part of the plug which can be inserted into the ear comprising a soft, pliable and hollow capsule element which is at least partially filled with a pliable or resilient filler and each plug comprising an end closure part for the hollow capsule element, the end closure part comprising a centrally arranged socket, and each opposite end part of the headband being provided with a ball end element for receiving in the socket of the end closure parts forming a joint connection, and the hearing protection device is characterized by the end distance the grinding part comprises a channel leading into the socket and comprises a chamfered surface to thereby form a cone-shaped stop surface to limit the degree of tipping of the plug.

The invention is explained in more detail below with reference to the drawings, of which

Fig. 1 is a schematic front elevation partly in the form of an X-ray drawing of a hearing protection device according to the invention. Fig. 2 is a schematic longitudinal section through an ear closure plug 20 according to Fig. 1, and Fig. 3 is a schematic longitudinal section through another embodiment of the ear closure plug 20 according to Fig. 1.

In the drawings, the same reference numbers have been used to indicate the same parts of the hearing protection device according to the invention. It appears from Fig. 1 and 2 that the hearing protection device according to the invention comprises a generally U-shaped spring headband 1 with an inwardly directed ear canal closure plug 20 attached to the opposite end parts 3 and 5 of the headband. The ear canal closure plugs 20 are hinged to the end parts 3 and 5 so that the plugs can be freely tipped horizontally and vertically. Each of the plugs 20 consists of a heavy, smooth, pliable and hollow capsule element 22 with a size and shape that allows it to be partially inserted into the ear canal. Because of this combination of features, the plugs 20 are forced under the influence of the spring headband partially into the ear canals and close them. Due to the fact that the plugs 20 are hingedly attached to the end parts 3 and 5 of the headband, the plugs 20 can be freely tipped and adjusted in relation to the user's natural ear canal angles, so that they can be placed in them while achieving maximum blocking effect and without the need for the user to make an external adjustment of the position of the plugs. This is an important advantage of the hearing protection device according to the invention as it is often the case that a person's ear canals are not exactly symmetrical in relation to each other. It has also been shown that known hearing protection devices often require the user to make a significant adjustment of the ear canal contact parts in order to achieve maximum blocking effect and that these adjustments are often insufficiently or sloppily performed or neglected, whereby the user does not receive the maximum hearing protection that the hearing protection device should be able to provide . With the hearing protection device according to the invention, however, these adjustments, which can be complicated, will take place automatically.

The main purpose of the generally U-shaped headband 11 is of course that it should act as a support device for the ear canal closure plugs 20 and act as a biasing device to force the plugs 20 into the ear canals so that they close them. Taking these conditions into account, the design, construction and the materials that can be used in the production of the headband 1 will, of course, vary greatly. The headband 1 can be made of a metal spring and be made in one piece or in several pieces. Thus, two curved, flat spring elements can be kept intertwined

in each other and so that they can slide in relation to each other, thereby achieving a U-shaped construction with adjustable length. In order to achieve low weight and a simple construction in one piece, however, it is preferred that the headband 1 is suitably formed from a rigid, resilient, polymeric, preferably thermoplastic, material, such as a rigid polyvinyl

chloride or polyacetal resin. With this construction, an easily manufactured headband 1 with a low weight is thus obtained which at the same time has a sufficient permanent bending modulus to hold the plugs 20 in the ear canals so that they close these at all times during use of the hearing protection device.

It has been shown that the spring force exerted by the spring headband 1 against the plugs 20 when the hearing protection device is arranged is of importance as the spring force must be sufficient to effect an effective closure of the ear canals while at the same time it must not be so strong that the user will be

set for discomfort. Due to the construction according to the invention of the plug 20, it has been shown that this spring force does not need to be large, and this greatly contributes to the fact that the hearing protection device according to the invention can be used without discomfort for the user. According to the invention, e.g. proved that a suitable biasing of the plugs 20 is achieved when the headband has such a construction and composition that when the opposite free ends of the headband (represented by the balls 7 and 9 in the embodiment shown in Fig. 1) are kept at a distance from each other of 14 .35 cm, an inwardly directed, recovering biasing force of 50-300 g (0.49-2.94 N), preferably 100-200 g (0.98-1.96 N), occurs. A suitable measurement of this recovering biasing force can be easily carried out by holding one end of the headband 1 in a fixed position while the other end of the headband is pulled out to the indicated distance by means of a spring weight. This measurement can also be easily carried out in a similar way by holding one end of the headband 1 in a fixed position, while the other end of the headband is suspended below the fixed end and loaded in increments with known weights until the indicated distance of 14.35 cm is achieved. Control of the recovering biasing force can be achieved by suitable sizing of the headband 1, the choice of construction materials for this or combinations of these precautions.

The construction of the ear canal closure plugs 20 is of great importance according to the invention as it is of essential importance that the plugs have a size and a shape that is such that they are suitable for partial introduction into the ear canals and

so that at least the parts of the plugs that can be introduced

in the ear canals, is constituted by a smooth, soft, pliable and hollow capsule element 22. Considering these needs, the capsule element 22 is made of a soft, smooth and pliable elastomeric or plastomer material, such as softened polyvinyl chloride, silicone rubber, ethylene/vinyl acetate copolymer, styrene/butadiene block copolymers, ethylene/propylene/diene rubber, neoprene rubber, polyurethane rubber or natural rubber, etc. The hardness of the construction material of the capsule element 22 determined by being Ice temperature with the Shore A hardness measuring apparatus method described in ANSI/ASTM D 2 24 0-75, can lie within the range 10-80, preferably 20-50.

The capsule element 22 preferably has a cone shape. When

such a cone-shaped capsule element 22 is used, the end of the element which has the smallest diameter will of course constitute the insertable free end of the ear canal closure plug 20, while the end of the element with the largest diameter will constitute the outer end for connection with the end part of the headband 1 3 or 5.' The intermediate angle defined by a cone-shaped capsule element 22 can be 15-45°, preferably 20-30°. The smallest end of a cone-shaped capsule element 22 can have a diameter of 0.3-1.2 cm, preferably 0.51-0.76 cm.

The space 24 which is delimited by the hollow capsule element 22 is at least partially filled with a resilient or pliable filler 26. When the capsule element 22 is hermetically sealed, the filler 26 can be in the form of a fluid, such as water, oil or air. However, the filler 26 is preferably solid or semi-solid and springy or pliable, such as silicone putty or consistency grease, glass wool, polyester fiber wool, polyurethane foam or polyvinyl chloride foam, etc. A particularly useful material for use as filler 26 in the hearing protection device according to the invention is an externally softened polyvinyl chloride foam, since the nature and the concentration of the plasticizer is such that the finished foam has a slow recovery rate after deformation and a low applied recovery pressure when it is deformed.

The wall thickness of the capsule element 22 can vary greatly and is usually not of decisive importance for achieving a hearing protection device according to the invention, provided that the capsule element retains its pliable property. The thickness will generally be 0.0013-0.076 cm, preferably 0.025-0.051 cm.

The ear canal closure plugs 20 are hinged

to the end parts 3 and 5 of the headband 1 so that the plugs 20 can freely tip both horizontally and vertically under the influence of the recovering biasing force developed by the spring headband 1.

The fastening device for the joint connection consists of

a ball joint, as shown in the drawing. According to this, the end parts 3 and 5 of the headband 1 are provided with end balls, respectively.

7 and 9. The balls 7 and 9 can form separate and separate elements of the headband construction or they can be made in one piece with the headband. The outer end of each capsule plug element 22 receives an end closure part 28 with a centrally arranged socket 30 with a diameter such that the socket can receive the balls 7 or 9. The center point of the joint connection between the plug 20 and the end part 3 or 5 of the headband 1 is preferably at or within, rather than outside, the outer end of the plug 20. When the latter feature is used, the propensity of the plug 20 to fold under the influence of the headband 1 becomes minimal. According to the embodiment of the invention shown in Fig. 2, the geometric center of the receptacle 30, or in other words the center point of the joint connection, is arranged on the plane defined by the outer end of the capsule element 22, and it is thus located within the outer end of the plug 20 end. The channel 32 which leads to the socket 30 is chamfered internally so that it forms a cone-shaped stop surface 34 which, when brought into contact with the surface of the end part 3 or 5 of the headband 1 by tipping the plug 20, will limit further movement of the plug 20 The construction material used in the manufacture of the shut-off part 28 should preferably have a sufficient springing ability that the ball 7 or 9 will be received in the socket 30 simply by pressing the ball 7 or 9 into it. For this reason, the closure part 28 of the plug 20 is preferably made of a resilient, polymeric material which, for the sake of simplicity and compatibility, can generally be of the same type as the material used in the production of the capsule element 22.

It should be noted that although the term "headband" has been used here in connection with the part designated 1 in the drawing, this term is not intended to be restrictive in terms of the particular way in which the construction is used. Although the hearing protection device according to the invention can of course be used with its headband 1 arranged directly above the user's head, e.g. substantially the same advantages when using the hearing protection arrangement are achieved when the headband 1 is worn behind the neck or is placed under the user's chin. In certain cases, such as when the user must also wear space-consuming headgear, a gas mask or eye protection, it may actually be necessary for the headband 1 to be placed either behind the neck or under the chin.

Another embodiment of the present hearing protection device is shown in Fig. 3. This shows a stopper 20, a capsule element 22, a space 24, a filler 26 and a shut-off part 28. The shut-off part 28 consists of a connecting part 36 and a connecting part 38. The connecting part 36 enables the joint connection described above. The connecting part 38 is used to attach to the capsule element 22. The connecting part 36 and the connecting part 38 are separated from each other by a section 40 and a free space 42. The free space 42 means that the shut-off part will become more flexible and that it can be grasped and inserted with greater comfort, and this in turn results in a more comfortable stopper. The connecting part 36 and the connecting part 38 move towards each other so that they come into contact with each other when a plug is grasped and introduced into an ear canal.

Example 1

The outer elements of two plugs 20 of the type shown in Fig. 2 were produced in pressure molds using a two-part heat vulcanized silicone rubber (Silastic 9591). Vulcanization was carried out in the mold for approx. 10 minutes at a temperature of approx. 177°C. The Shore A hardness of the vulcanized material at room temperature was approx. 60. These

The essential dimensions of external elements were as follows:

The 2 2 spaces 24 of the capsule elements were each filled with a cylindrical plug which, in the untensioned state, had a diameter of approx. 1.37 cm and a length of approx. 1.8 cm, the plug being made of a highly softened, predominantly closed-cell polyvinyl chloride foam material. The plug was introduced by first rolling it between the fingers, after which it was introduced into the space 24 and then allowed to expand. Then the shut-off part 28 was firmly cemented to the capsule element 22 by means of a silicon rubber cement which hardens at room temperature.

The generally U-shaped headband 1 for this construction consisted of rigid polyvinyl chloride and was made by injection molding the resin into the shape shown in Fig. 1.

The resulting molded article had a diameter of 0.48 cm. The bending radius of the headband 1 upper part was 6.35 cm, the length of each of the straight side arm sections of the headband was approx. 8.76 cm, and both end parts 3 and 5 were bent inwards so that they formed an angle of approx. 85° in relation to the corresponding straight side arm section. The total length of the headband 1 was 16 cm. The opposite ends of the manufactured headband were formed into balls 7 and 9 each having a diameter of 0.64 cm and forming one piece with the headband. When the headband 1 was in an untensioned state, there was a free space between the balls 7 and 9 of 5.7 cm. When the headband balls 7 and 9 were separated from each other up to a distance of 14.35 cm, it was found that the recovering bias force was approx. 180g (1.7N).

The hearing protection device according to this example was then assembled by each of the balls 7 and 9 being manually placed in a socket 30 in the plugs 20.

The results of tests carried out using this hearing protection device are reproduced in example 4.

Example 2

The elements 22 and 28 for two plugs 20 with essentially the same shape and dimensions as those described in example 1 were made by compression molding of a polyvinyl chloride plastisol material containing the following components:

The Shore A hardness of the surface molten material was approx. 50. The space 24 of the capsule elements 22 was filled with a plug of polyvinyl chloride foam of a similar type as used in example 1. The capsule elements 22 were then cemented firmly to the shut-off parts 28 by means of a two-component polyurethane adhesive to complete the construction of the two plugs 20.

The construction according to this example of the headband 1 is essentially the same both in terms of shape and dimensions as according to example 1. However, for the present example, the headband 1 was produced by injection molding a polyacetal resin (Delrin ® , produced by E.I. du Pont

de Nemours and Co., Wilmington, Delaware). When the ends of the headband were separated from each other up to a distance of 14.35 cm between the balls 7 and 9, the obtained inwardly directed, regaining bias force was determined to be approx. 142g (1.4N).

The hearing protection device was completed by manually fitting the plugs 20 to the headband 1, and the resulting hearing protection device was examined by the method described in example 4.

Example 3

The members 22 and 28 of a pair of plugs 20 were made by injection molding a heat vulcanized silicone rubber SWS-7655, manufactured by SWS Silicones Corp., Adrian, Michigan. Vulcanization in the form of the die-cast elements was carried out in approx. 10 minutes at a temperature of approx. 177°C. The Shore A hardness of the vulcanized silicone rubber was approx. 50. The space 24 of the capsule elements 22 was filled with plugs of polyvinyl chloride foam of the type and in the same manner as described in example 1. The capsule elements 22 were then firmly cemented to the shut-off parts 28 using a silicone rubber cement which hardened at room temperature. The finished plugs 20, which had essentially the same dimensions as the plugs according to example 1 or 2, were then fitted to a headband 1 which had essentially the same dimensions and the same shape as the headbands used in example 1 or 2 However, according to the present example, the headband 1 was made by injection molding the resin Celcon ® which is a highly crystalline acetal copolymer manufactured by Celanese Chemical Co., New York, N.Y. When this headband 1 was bent open so that its ball elements were at a distance from each other of 14.35 cm, the resulting recovering bias force was approx. 174g (1.7N).

The hearing protection device obtained was then examined using the method described in example 4.

Example 4

The hearing protection devices according to examples 1-3 were subjected to comparison tests with each other and with several commercially available known hearing protection devices of a generally similar type. Audiometric data were obtained together with comments from the subjects regarding the comfort and ease of use of the hearing protection devices used.

Three people took part in the experiments, and the experiments with h<y>er hearing protection device were repeated three times for each of the people. The subjects who took part in the experiments were all asked to adjust the hearing protection devices' shut-off elements as best as possible to achieve a maximum sound attenuation effect for each hearing protection device. The sound test method used was ANSI S3.19, which was only changed to the point that three people instead of the specified ten people took part in the tests. For the sake of simplicity, the sound measurement analyzes are reproduced in the table 1 below as a single number denoted by the Sound Reduction Number (LRT). The method used to transfer sound measurement test results according to ANSI S3.19 to LRT assessment in the form of a single number is described in detail in the thesis "Single Number Measures of Hearing Protector Noise Reductions", by Elliott H. Berger, " E-A-RLOG1} E-A-R Corporation, Indianapolis, Indiana, 1979. It should be noted that for each of the known hearing protection devices, the ear canal closure members were not articulated with the headband member.

Example 5

Several hearing protection devices are produced using the PVC headband 1 according to example 1 and plugs 20 of the type that was produced according to example 3. In the present example, different fillers 26 are used to fill the space 24 of the capsule elements 22. The obtained hearing protection devices are subjected to sound measurement examination by a single subject using the test apparatus and method according to ANSI S3.19. The results of these tests are reproduced in Table II below.

Claims (2)

1 • Hearing protection device of the type comprising a generally U-shaped spring headband (1) which attached to each of its opposite end portions (3,5) has an inwardly directed ear canal contact portion each of which has a first end portion (20) which can be forced by the spring headband into an ear canal blocking condition, and an opposite end part with external dimensions that are sufficiently small that it will be surrounded by the auricle and is directly connected to an end part (3,5) of the headband, the first end part of each of the ear canal contact parts comprising a sealing plug (20), at least the part of the plug (20) that can be inserted into the ear comprises a soft, pliable and hollow capsule element (22) which is at least partially filled with a pliable or resilient filler (26) and each plug (20) comprises an end closure part (28) for the hollow capsule element (22), where the end closure part (28) comprises a centrally arranged socket (30), and each opposite end part (3,5) of the headband (1) is provided with a ball end element (7, 9) for receiving in the socket (30) of the end shut-off parts (28) while forming a joint connection, characterized in that the end shut-off part (28) comprises a channel (32) which leads into the socket (30) and comprises a chamfered surface to thereby form a cone-shaped stop surface (34) to limit the degree of tipping of the plug (20). 2. Hearing protection device according to claim 1, characterized in that the end closure part (28) of each plug (20) consists of a connecting part (36) to create the joint connection (7,30;9,30) and of a connecting part (38) to be attached to the capsule element (22), the connecting part (36) and the connecting part (38) are located at a distance from each other and so that they come into contact with each other when a plug (20) is grasped and introduced into an ear canal.