RU169518U1 - WARMED THERMAL CONTROLLING JACKET - Google Patents

Abstract

The utility model relates to the production of outerwear, in particular to the production of casual, work clothes, clothing for motorists, suitable for use in the cold period of time. The insulation layer is made in the form of shelves and backs from a non-woven heat-saving fabric with sections laid on it. A layer of non-woven heat-insulating material with a foil perforated coating is laid on the upper sections of the middle parts of the shelves to the line of the chest and the upper section of the middle part of the back to the line of the shoulder blades. On the sections of the shelves from the chest line to the waist line and the back section from the line of the shoulder blades to the waist line - a layer of damping temperature difference of the material with a phase transition. The backing layer contains several stitched sections. In the middle of the back, the section is made of mesh material. In the shoulder area on the lateral parts of the back and shelves and in the upper part of the sleeve - from breathable lining fabric with foil perforated coating. Each barrel from the armhole to the waistline contains two sections. The upper section is made of mesh material. The lower section and the side parts of the back are made of a moisture-removing knitted fabric. The technical result is an increase in thermostatic ability. 3 of FIG.

Description

The utility model relates to the production of outerwear, in particular, to the production of casual, work clothes, clothing for motorists, suitable for use in the cold period of time.

Known insulated thermostatic jackets made of the main package of materials, including a waterproof top layer, a layer of insulation and a breathable lining (EP 0516629 B1, WO 2015051370 A2, WO 2005110135 A2, US 2005246813 A1).

Known jackets are made of a main package of materials containing at least one thermoregulating section made of a material with reduced heat-insulating ability and / or with increased ventilation ability, located with the possibility of overlapping at least part of the temperature-sensitive region of the body. Known jackets make it possible to increase the thermoregulation of the clothing space, however, under changing external temperature conditions, effective thermoregulation is not achieved.

Closest to the proposed utility model is the well-known insulated thermostatic jacket, made of the main package of materials, including a waterproof top layer, a layer of insulation and a lining layer containing breathable lining fabric, equipped with cooling cavities formed by unfastening the zippers on the details of the jacket (RU 116019 U1).

In the process of active movements of a person wearing a well-known jacket, when the zippers are unzipped, cooling channels are formed that work on the principle of a wind tunnel, inside of which a powerful air stream is created. This flow pushes out heated air, thereby increasing the rate of regulation of heat transfer of the human body with the environment. However, if a person dressed in a jacket does not make active movements, then effective cooling does not occur and overheating of the clothing area is inevitable. In this case, due to the sweat released, the lining fabric and the adjacent layer become especially wet. When a person dressed in such a jacket goes out into the cold air, even for a short time, required, for example, for a car enthusiast to get from the car to the entrance of the house, or for a security guard to leave the working room and check the vehicles leaving the guarded territory, undercoating will inevitably occur space due to the fact that the thermal conductivity of wet clothes is much higher than dry.

The technical problem is to create a thermally insulated jacket, deprived of this drawback.

The technical result of the proposed utility model is to increase its thermoregulatory ability.

The specified technical result is achieved by the fact that in a thermally insulated jacket, made of the main package of materials, including a waterproof top layer, a layer of insulation and a lining layer containing breathable lining fabric, the insulation layer is made in the form of shelves and backs and is a non-woven heat-saving fabric with stitched on it from the side adjacent to the lining layer, areas covering the middle parts of the shelves and backs, and on the upper parts of the middle parts shelves to the chest line and the upper part of the middle part of the back to the line of the shoulder blades, a layer of non-woven heat-insulating material with foil perforated coating is scribbled, and a layer of damping temperature difference of the material with phase is laid on the sections of the shelves from the chest line to the waist line and the back section from the line of the blades to the waist line transition, the lining layer contains the following stitched sections: in the middle part of the back - a section made of mesh material, in the shoulder area on the side parts of the back and shelves, as well as in the top parts of the sleeve — sections made of breathable lining fabric with a foil perforated coating, each barrel from the armhole to the waist line contains two sections, the upper section made of mesh material, and the lower section, as well as the side parts of the back, of a moisture-knitting canvases.

The causal relationship between the totality of essential features and the technical effect provided by the utility model is based on well-known locations on clothing that require reduced and increased thermal insulation ability, and the principles of enhancing heat and steam exchange through these areas (see, for example, EP 0516629 B1 ) and consists in the following.

The insulation layer is made in the form of shelves and backs and is a non-woven heat-saving fabric with a patch on it from the side adjacent to the lining layer, areas covering the middle parts of the shelves and backs. At the same time, a layer of non-woven heat-insulating material with a foil perforated coating reflecting heat in the direction of the lining layer is laid on the upper sections of the middle parts of the shelves to the line of the chest and the upper section of the middle part of the back to the line of the shoulder blades. On the sections of the shelves from the chest line to the waist line and the back section from the line of the shoulder blades to the waist line there is a layer of damping temperature difference of the material with a phase transition. Materials with a phase transition are able to change their state from solid to liquid and vice versa under certain temperature conditions, absorbing or releasing heat. Thus, sections of clothing made from such a material react to temperature fluctuations and level them. If the temperature of the clothing area rises, excess heat accumulates in the material, as it were, and then is used to lower the temperature of the clothing space to heat it.

The lining layer contains stitched sections made of materials with different heat-conducting and ventilation abilities. So, in the middle of the back is a section of mesh material that performs a ventilation function. In the area of the shoulders on the lateral parts of the back and shelves, as well as in the upper part of the sleeve, there are sections made of breathable lining fabric with a foil perforated coating that reflects heat in the direction of the clothes area. Each barrel from the armhole line to the waist line contains two different sections: the upper section of mesh material performs a ventilation function in the armpits, and the lower section is made of a moisture-removing knitted fabric. The side parts of the back are made of such material.

In FIG. 1-3 presents a schematic representation of one of the possible special cases of a specific implementation of the proposed utility model. In FIG. 1 shows a layer of insulation (from the side adjacent to the lining layer), in FIG. 2 - a lining layer of shelves and backs, in FIG. 3 - lining layer of the sleeve. The insulation layer (Fig. 1) is a shelf and backrest made of non-woven heat-saving fabric 1, which can be used, for example, Valtherm material (http://signorina-primavera.com/article/2-article/9-valtherm .html), with tapered sections of non-woven heat-insulating material with foil perforated coating 2, which can be used, for example, non-woven polyester material coated with perforated aluminum foil Gamtag (http://textiletr.ru/catalog/sintepon/ orv_manufacturing_spa_italiya / uteplitel_dlya_verhney_odzhdi_1368619700 /) and part with damping temperature differences of the material with a phase transition 3, which can be used, for example, any of Schoeller's commercially available materials (http://old.sivera.ru/ru/technologies/Materials/5). obtained using PCM technology (Phase Change Material), such as ComforTemp (http://www.comfortemp.com/), including microscopic balls filled with paraffin. The lining layer of the shelves and backs (Fig. 2) and sleeves (Fig. 3) are stitched sections made of materials with different heat-conducting and ventilation abilities. Sections 4 (the upper section of the barrel and the middle part of the back) can be made of any mesh lining material (for example, http://www.balt-tex.ru/165/184). preferably from a knitted mesh volumetric structure. Sections 5 (in the shoulder region on the lateral parts of the back and shelves and the upper part of the sleeve) can be made of any commercially available breathable lining fabric with a foil perforated coating, in particular with a foil print (for example, http: //www.oldos. com / textile / stati / podkladochnaya-tkan /). Sections 6 (the lower section of the barrel and the side parts of the back) can be made of any moisture-removing knitted fabric, for example, polyester. Sections 7 can be made of any breathable lining fabric. The top layer of the main package of materials can be made of any commercially available waterproof material used for the manufacture of outerwear.

Examples

The prototype jacket is made according to RU 116019 U1 from the main package of materials, including the top layer made of waterproof jacket polyester material, the insulation layer made of Valtherm material and the lining layer made of breathable polyester lining fabric. Moreover, according to RU 116019 U1, the zippers were placed symmetrically, two on each of the sleeves, two on the shelves and two on the back, the unfastened parts consist of a package of materials including a heater placed between the waterproof top layer and the breathable lining fabric. The base of the channels is made of non-perforated airtight fabric so that cooling cavities (channels) are formed along the lateral parts of the jacket and on the upper part of the sleeve with the subsequent exit on the back and in the elbow seam of the sleeve in the form of an opening.

The jacket according to the proposed utility model is made of the main package of materials, including the top layer made of waterproof jacket polyester material used in the prototype jacket, a layer of insulation and a lining layer. In this case, the insulation layer is a shelf and backrest 1 made of Valtherm material used in the prototype jacket, with sewn sections 2 of non-woven heat-insulating material coated with perforated Gamtag aluminum foil and sections 3 of damping temperature difference material with a ComforTemp phase transition. The lining layer of shelves, backs and sleeves contains stitched sections made of materials with different heat-conducting and ventilation capacities, namely: sections 4 made of knitted mesh, sections 5 made of lining fabric with foil print, sections 6 made of knitted polyester fabric and sections 7 - from breathable polyester lining fabric used in the prototype jacket.

For testing, both jackets were equipped with liquid crystal thermometers made in the form of strips and sewn onto the jacket lining from the side facing the body of the tester, on one of the shelves and in the middle of the back.

Jacket tests were performed by one tester under identical conditions: 60 min. driving a car at a cabin temperature of 17 ° C and after exiting the car for 10 minutes. at outdoor temperature minus 10 ° С. The temperature of the clothing area before the experiment was the same for both jackets and was 30 ° C. On the prototype jacket, the zippers were unfastened at the beginning of the test (two on each sleeve, two on the shelves and two on the back) to open the cooling cavities and buttoned after the tester exited the car. The jacket according to the proposed utility model remained fully buttoned from the beginning to the end of the experiment. After a 60-minute stay in the car, the temperature of the clothing space for the prototype jacket was 38 ° C, and for the jacket according to the proposed utility model, the temperature of the clothing space was 32 ° C. After a 10-minute stay in cold air, the temperature of the clothing space for the prototype jacket decreased by 8 ° С according to the readings of the thermometer placed on the shelf, and by 12 ° С - from the readings of the thermometer placed on the back, which is explained by the especially high humidity of the lining and the adjacent to her a layer of the main package of materials in the back. After a 10-minute stay in cold air for a jacket according to the proposed utility model, the temperature of the entire clothing space, according to the readings of both thermometers, decreased uniformly by 3 ° C and amounted to 29 ° C.

Claims (1)

An insulated thermoregulating jacket made of the main package of materials, including a waterproof top layer, a layer of insulation and a lining layer containing breathable lining fabric, characterized in that the insulation layer is made in the form of shelves and backs and is a non-woven heat-saving fabric with side wired on it adjacent to the lining layer, areas covering the middle parts of the shelves and backs, and on the upper parts of the middle parts of the shelves to the chest line and the upper a portion of the middle part of the back to the line of the blades is coated with a layer of non-woven heat-insulating material with a foil perforated coating, and on the sections of the shelves from the chest line to the waist line and the section of the back from the line of the blades to the waist line is a layer of damping temperature difference of the material with a phase transition, the lining layer contains the following sewn sections: in the middle part of the back - a section made of mesh material, in the shoulder area on the lateral parts of the back and shelves, as well as in the upper part of the sleeve - sections performed made of breathable lining fabric with foil perforated coating, each barrel from the armhole line to the waist line contains two sections, the upper section made of mesh material, and the lower section, as well as the side parts of the back, of a moisture-removing knitted fabric.

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