EP0736267A2 - Thermal insulating cap and footwear provided therewith - Google Patents

Abstract

Shoe has a thermally insulating toe-cap made of an air-trapping material (51) able to retain its air trapping quality under compression at pressures arising during normal use. Pref. the cap is made of a closed or open-pored plastic foam, partic. being made of a nonwoven polyester material felt. It is pref. provided with at least one water vapour-impermeable functional layer (53), partic. of micro-porous polytetrafluoroethylene, which may be on the inside and/or outside of the air-trapping material. Cap may have textile lining layer (49) of knitted material made up of polyamide and polyester. Also claimed is footwear with a thermally insulating cap only in the toe area and a removable sole insert with an insulating cap at the toe region.

Description

The invention relates to a thermal insulation cap and footwear equipped therewith.

Footwear worn in a low temperature environment must keep the feet of the person wearing such footwear sufficiently warm. Winter shoes, hiking boots, etc. are therefore usually lined with warm lining.

The toe area of the foot proves to be particularly critical. The foot feels the strongest temperature in the toe area. The blood flow can be changed in a ratio of about 1: 100 in order to maintain the body temperature in the toe area. At low ambient temperatures, there is a temperature gradient of around 5 ° C between the toe root joint and the tip of the toe.

Due to the construction of a shoe, there is often a thinner overall material structure in the toe area than in the shaft area. In addition to the aspect that there is a temperature gradient of around 5 ° C in the toe area, there is often the thinnest, least heat-insulating area of the shoe.

This problem is to be overcome with the present invention.

One solution of the invention consists in a heat insulation cap, with which the footwear can be lined in the toe area, the heat insulation cap being constructed with an air-storing material which has such a compression resistance that it is at compression pressures which arise during normal use of the footwear the material is exercised, air storage capacity and thus insulated wedge remains.

The ability to store air ensures thermal insulation in the toe area, since the air in the air-storing material that is warmed by the foot represents a thermal insulation layer.

The air-storing material can be closed-pore or open-pore, for example a porous plastic foam or felt. Closed-pore material has the advantage that no moisture can penetrate into the pores, which would displace the heated air stored in the material and impair the thermal insulation.

The heat insulation cap can be provided with a waterproof, water vapor-permeable functional layer, which is preferably constructed with microporous polytetrafluoroethylene (PTFE). The functional layer can be arranged on the outside facing the upper of the footwear, on the inside facing away from the upper or on both sides of the air-storing material. A functional layer arranged on the outside of the air-storing material prevents moisture from penetrating into the air-storing material from the outside and thus impairing the thermal insulation ability of this material. A functional layer arranged on the inside of the air-storing material prevents sweat moisture, which is emitted by the foot through the air-storing material and condenses to water outside the functional layer, can return to the foot. Most preferred is the arrangement of a waterproof, water vapor-permeable functional layer both on the outside and on the inside of the air-storing material. In this case, moisture coming from outside is prevented from penetrating into the air-storing material and impairing its thermal insulation, and also that sweat moisture, which condenses, for example, on the inside of the outer functional layer, gets back to the foot.

Particularly preferred is a heat insulation cap that is constructed with a laminate that has a layer of air-storing material, a textile lining layer on the inside, and a waterproof, water-vapor-permeable functional layer on the outside and / or on the inside of the layer of air-storing material.

The invention also makes available footwear that is lined with a thermal insulation cap according to the invention only in the toe area. Increased thermal insulation therefore only takes place in the toe area. The rest of the foot is not overheated.

Footwear that is supposed to be suitable for low ambient temperatures is usually provided with a shoe lining lining the interior of the footwear, at least the upper. The thermal insulation cap according to the invention is then additionally arranged in the toe area of the footwear. The shoe lining can be adapted to the heat requirement of the entire foot. The higher heat requirement in the toe area is taken into account by the additional heat insulation cap.

The thermal insulation cap can be arranged between the shoe lining and the upper material of the footwear. In the event that the footwear is lined with a sock-like insert that is constructed with a waterproof, water vapor-permeable functional layer, the heat insulating cap can be arranged inside the sock-like insert.

The versatility of the footwear is particularly great if you place the thermal insulation cap on the toe area of an insole, which can optionally be inserted into the footwear. At low ambient temperatures, the insole with the thermal insulation cap is inserted into the footwear and at higher ambient temperatures, the insole with the thermal insulation cap is removed from the footwear. Instead of the insole with the heat insulation cap, another insole can then be inserted into the footwear, which is provided in the toe area with a filler cap instead of the heat insulation cap, which would otherwise be used by the heat insulation cap Fills the inner part of the footwear, but has no heat insulation properties and therefore does not heat the toe area of the foot.

Conventional shoes are often provided with a shape stabilization cap, which is intended to ensure the shape stability of the footwear in the toe area. This is mostly polyvinyl mixed with fabric, which, however, has no air storage capacity and therefore no thermal insulation volume.

There are now two possibilities for replacing the conventional shape stabilization cap with the heat insulation cap according to the invention or for maintaining the conventional shape stabilization cap and for the heat insulation cap being additionally inserted into the toe space of the footwear.

Further configurations of the thermal insulation cap according to the invention, the footwear according to the invention and the insole according to the invention result from the appended claims.

Figur 1

eine schematische Darstellung eines Halbschuhs, der mit einer erfindungsgemäßen Wärmeisolierkappe versehen ist;

Figur 2

eine schematische Darstellung eines Futterzuschnittes in Form eines Futterblattes, an dem eine erfindungsgemäße Wärmeisolierkappe befestigt ist;

Figur 3

eine schematische, nicht maßstabsgerechte Schnittansicht des Futterzuschnittes und der Wärmeisolierkappe nach Figur 2;

Figur 4

einen Halbschuh, in den eine Einlegesohle mit daran angeordneter Wärmeisolierkappe oder Füllkappe eingelegt ist;

Figur 5

eine schematische Darstellung einer Einlegesohle mit daran angeordneter Wärmeisolierkappe oder Füllkappe;

Figur 6

eine schematische, nicht maßstabsgerechte Schnittansicht eines Teils der in Figur gezeigten Wärmeisolations- oder Füllkappe; und

Figur 7

einen Kappenzuschnitt für die Herstellung einer Wärmeisolations- oder Füllkappe gemäß Figuren 4 und 5.

The invention will now be explained in more detail by means of embodiments. The drawings show:

Figure 1

a schematic representation of a shoe, which is provided with a thermal insulation cap according to the invention;

Figure 2

a schematic representation of a feed blank in the form of a feed sheet to which a heat insulating cap according to the invention is attached;

Figure 3

a schematic, not to scale sectional view of the lining blank and the heat insulating cap according to Figure 2;

Figure 4

a shoe in which an insole with a thermal insulation cap or filler cap arranged thereon is inserted;

Figure 5

is a schematic representation of an insole with heat insulation cap or filler cap arranged thereon;

Figure 6

is a schematic, not to scale, sectional view of part of the heat insulation or filler cap shown in the figure; and

Figure 7

a cap blank for the production of a heat insulation or filler cap according to Figures 4 and 5.

FIG. 1 shows a schematic representation of a shoe 11, which in the usual way has a shaft 13, an insole 15 and an outsole 17, and whose shaft 13 is constructed with an upper 19 and a lining material 21 lining the upper 19. According to the invention, a heat insulation cap 23 is provided which only lines the toe region 25 of the shoe 11. The heat insulating cap 23 is located between the upper material 19 and the lining material 21. The remaining area of the shoe 11 is only with the lining material 21 lined so that increased heat insulation occurs only in the toe area of the shoe 11.

FIG. 2 shows a lining sheet 27 which is intended to form part of the lining material 21 of the shoe 11. In FIG. 2, one can see from above the side of the lining 27 that faces the upper 19 in the finished shoe 11. The lining sheet 27 has a toe region 29 at the top in FIG. 2 and a tongue connection region 31 at the bottom in FIG. 2, which is sewn to the shoe tongue. On the side of the lining sheet 27 facing the upper material 19 in the finished shoe 11, a heat insulating cap sheet 33 is fastened by means of a transition web 35. For this purpose, the lower longitudinal side edge 37 of the transition web 35 in FIG. 2 is sewn onto the lining sheet 27 with the aid of a lining seam 39. At the upper longitudinal side edge 41 of the transition web 35 in FIG. 2, the end of the heat insulating cap sheet 33 remote from the toe region 25 is sewn by means of a cap seam 43.

The combination of lining sheet 27 and heat insulating cap sheet 33 shown in FIG. 2 is intended for shoes, the shaft 13 of which is connected to the insole 15 of the shoe 11 by pinching. The insole 15 is fastened to the sole side of a shoe last and the upper 13 is then placed on the top of the last. A lower end region of the shaft 13 projects beyond the underside of the last. This protrusion or lasting fold is then pulled around the sole-side circumference of the last on the underside of the insole 15 and glued there. In the same way, the composite of lining sheet 27 and heat insulation cap sheet 33 shown in FIG. 2 is placed over the last and pulled around the outer contour of last and insole 15 and glued to the underside of insole 15. Since the heat insulating cap sheet 33 is relatively thick due to the air-storing material, there is strong wrinkling in the area of the lasting fold of the thermal insulating cap sheet 33 when the circumferential area of the thermal insulating cap sheet 33 is knocked over or twisted 47 divided and these lasting flaps 47 are sharpened on the other hand, so that the thickness of the lasting flaps 47 decreases towards their free ends.

For use in a waterproof, breathable shoe, both the lining sheet 27 and the heat insulating cap sheet 33 can be provided with a waterproof, water vapor-permeable functional layer. So that their water vapor permeability is not prevented, the heat insulating cap sheet 33 must not be completely in love with the lining sheet 27. For this reason, in the embodiment shown in FIG. 2, the fastening between the lining sheet 27 and the heat insulating cap sheet 33 takes place via the seams 39 and 43. Alternatively, one could use a dot matrix glue or only circumferential glue between the lining sheet 27 and the heat insulation cap sheet 33.

For shoes that are not designed for water resistance, neither the lining sheet 27 nor the heat insulating cap sheet 33 need to be lined with a waterproof, water vapor-permeable functional layer. The same applies to shoes that are waterproof due to the use of a waterproof upper for the upper. For waterproof, breathable shoes that are waterproof but are permeable to water vapor, for example in order to be able to dissipate sweaty moisture from the foot, the lining sheet 27 is provided with a waterproof, water vapor-permeable functional layer. So that such shoes are breathable, upper 13 is used for the upper 13, which is permeable to air, but also permeable to water. Through the upper material 19, water penetrating from the outside therefore reaches the heat insulation cap 23 formed from the heat insulation cap sheet 33. In order to avoid that the air-storing material of the heat insulation cap 23, when it is constructed with open-pore material, becomes saturated with water and thereby has a heat insulation effect is impaired, a waterproof, water vapor-permeable functional layer can be arranged on the outside of the air-storing material of the heat insulating cap 23 facing the shaft 13. Because sweat moisture given off by the foot, particularly in cold ambient temperatures, points to the air-storing material Can collect inside of this functional layer as condensation, in a preferred embodiment, a waterproof, water vapor-permeable functional layer is also provided on the side of the air-storing material of the heat insulating cap 23 facing the lining sheet 27. This prevents such condensed water from returning to the foot of the person wearing the shoe. It is also possible to arrange a functional layer only on the side of the air-storing material of the heat insulating cap 23 that is remote from the shaft 13.

For an embodiment of the last-mentioned variant, FIG. 3 shows a sectional view of the composite shown in FIG. 2 with a lining sheet 27 and a heat insulation cap sheet 33. In this embodiment, the lining sheet 27 and the heat insulation cap sheet 33 are each formed from a laminate of the same structure. That is, the lining sheet 27 and the heat insulating cap sheet 33 are punched out of the same laminate and fastened one above the other with the same orientation with respect to the layer position.

• eine Futtermaterialschicht 49, vorzugsweise in Form einer textilen Futterwirkware;
• eine Luftspeicherschicht 51, die vorzugsweise durch ein kompressionsresistentes Filzmaterial gebildet ist;
• eine wasserdichte, wasserdampfdurchlässige Funktionsschicht 53; und
• eine Schutzschicht 55, vorzugsweise in Form von Kettstuhlwirkware, zum Schutz der Funktionsschicht 53 auf deren von der Luftspeicherschicht 51 abliegenden Seite.

The laminate of both the lining sheet 27 and the heat insulating cap sheet 33 has the following laminate layers as seen from the shaft 13 in the direction of the interior of the shoe, ie from top to bottom in FIG. 3:

• a lining material layer 49, preferably in the form of a textile lining material;
• an air storage layer 51, which is preferably formed by a compression-resistant felt material;
• a waterproof, water vapor permeable functional layer 53; and
• a protective layer 55, preferably in the form of warp knitted fabric, for protecting the functional layer 53 on its side remote from the air storage layer 51.

As already explained in connection with FIG. 2, the heat insulating cap sheet 33 is sewn onto the lining sheet 27 by means of the transition web 35, specifically by means of the cap seam 43 and the lining seam 39. Since the functional layer 53 of the lining sheet 27 is perforated by the lining seam 39, the lining seam 39 is sealed on the side facing the interior of the shoe by means of a waterproof sweatband 59. The sweatband 59 is also provided with a textile protective layer 61 for protection and mechanical stabilization.

In the construction shown in FIG. 3, water resistance and breathability for the foot are provided by the functional layer 53 of the lining sheet 27. The functional layer 53 of the heat insulation cap sheet 33 is actually only present because the heat insulation cap sheet 33 is stamped from the same laminate as the lining sheet 27.

In order to increase the functionality and thus the wearing comfort, the heat insulating cap sheet 33 can also be arranged in the reverse orientation of its laminate layers, ie with the functional layer 53 towards the shaft 13, that is to say upward in FIG. 3. This reduces the risk that the air storage layer 51 is soaked up with moisture which has penetrated through the shaft 13 from the outside and would impair the thermal insulation ability of the air storage layer 51.

For the same reasoning, the laminate of the lining sheet 27 could also be oriented in the opposite direction to that shown in FIG. likewise with its functional layer 53 facing the shaft, that is to say pointing upward in FIG. 3. In this case, the air storage layer 51 of the lining sheet 27 would be protected from being soaked up with liquid which penetrates through the shaft 13 to the lining sheet laminate.

The human foot has a particularly large number of sweat glands in the toe area, so that a particularly large amount of perspiration is generated in the toe area. This could condense at a cold ambient temperature on the inside of the functional layer 53 of the lining sheet 27 and in the toe area of the shoe 11 on the inside of the functional layer 53 of the heat insulating cap sheet 33. Liquid condensed on the functional layer 53 of the lining sheet 27 could run back to the foot and wet it. On the functional layer 53 of the thermal insulation cap sheet 33 condensing liquid could run back to the air storage layer 51 of the lining 27 and impair its thermal insulation ability. In order to avoid this, one functional layer 53 can be arranged both on the inside and on the outside of the air storage layer 51 of the lining sheet 27 and preferably also of the heat insulating cap sheet 33. In this way, on the one hand, the air storage layer 51 is protected from the ingress of moisture from the outside and, on the other hand, it is achieved that condensation water formed on the outer functional layer cannot get back to the foot. This is because the condensation of sweat moisture occurs mainly on the outside of the air storage layer 51, since the inside thereof will normally be so much warmer than the outside due to the warm air stored therein that the process of condensing sweat liquid is practically only on the outer functional layer 53 of the lining sheet 27 or the heat insulating cap sheet 33 occurs.

In the embodiment shown in FIG. 3, the lining sheet 27 and the heat insulating cap sheet 33 are fastened to one another by means of the transition web 35 and by means of the seams 39 and 43. You can also attach the thermal insulation cap sheet 33 to the lining sheet 27 by gluing. However, full-surface gluing should be avoided because this would hinder the breathability of the shoe 11 in the toe area, that is to say where there is a particularly high sweat moisture emitted by the foot due to an increased number of sweat glands. In the case of adhesive bonding, therefore, either a dot-matrix-type adhesive bonding or an adhesive bonding should only be carried out on the circumferential contour of the heat insulating cap sheet 33.

There are shoes whose shoe interior is lined with a sock-like insert ("bootie") which is constructed with a waterproof, water vapor-permeable functional layer. In such a shoe, the heat insulating cap 23 is fastened on the inside of the toe area of the sock-shaped insert, so that in principle the same structure is obtained as shown in FIG. 3. You can either the heat insulating cap 23 before introducing the Sew the sock-like insert into the interior of the shoe on the sock-like insert or stick it on the entire surface.

FIGS. 4 to 7 show an embodiment of the invention which makes it possible to change the heat-insulating capacity of a shoe 63 depending on the ambient temperature. For this purpose, an insole 65 is provided, on the toe area of which a heat-insulating cap 23 is attached. This can be built up, for example, with the laminate that is used in FIG. 3 both for the lining sheet 27 and for the heat insulating cap sheet 33.

At ambient temperatures at which the normal shoe lining lining the shoe 63 is not sufficient to sufficiently heat the temperature-sensitive toe area of the foot, the insole 65 can be inserted into the shoe 63 with the heat insulating cap 23. If the ambient temperature is so high that the thermal insulation cap 23 leads to overheating of the toe area, the insole 65 can be removed from the shoe 63. So that the interior of the shoe is not too large for the foot in this case, instead of the insole 65 provided with the heat insulating cap 23, an insole provided with a filling cap can be inserted into the shoe 63. The insole provided with the insulating cap 23 thus forms a winter insole, while the insole provided with the filler cap can be referred to as a summer insole. The summer insole with the filler cap has the same dimensions and dimensions as the winter insole so that the interior of the shoe is always the same size for the foot, regardless of whether the winter insole or the summer insole is inserted into the shoe 63. In contrast to the heat insulating cap 23 of the winter insole 65, the filling cap of the summer insole consists of a non-heating material which preferably has approximately the same compression resistance as the air storage material of the heat insulating cap 23. Suitable materials for the filler cap are, for example, coarse-mesh knitted spacer fabrics, knitted spacer fabrics or spacer nets.

FIG. 5 shows a schematic perspective view of an embodiment of an insole 65 with a heat insulation cap 23 attached to the toe region thereof. The heat insulation cap 23 is sewn to the insole 65 by means of a tension seam 67. So that there is no step at the insertion opening of the heat insulation cap 23 in the interior of the shoe, which on the one hand could impair the comfort of the shoe provided with the insole 65 and, on the other hand, when the shoe slipped into the interior of the shoe could lead to entrainment of the edge of the heat insulation cap 23 on the insertion opening side a wedge-shaped transition lip 69 serving as a slip-in aid, the thickness of which decreases in the direction of the heel region of the insole 65. So that the heat insulating cap 23 remains dimensionally stable in its slip-in area, an arcuate spring clip 71 is inserted into the transition lip, which is formed, for example, from a spring wire. In the vicinity of the transition lip 69, a Velcro fastener element 73 is arranged on the outside of the heat insulating cap 23, which can be hooked up with a counter Velcro fastener element at a corresponding point in the shoe interior in order to hold the heat insulating cap 23 in the toe area of the shoe interior.

The underside of the insole 65 can also be provided with at least one Velcro fastener element 75 in order to enable the insole 65 to adhere well within the shoe 63.

The heat insulation cap 23 can again be constructed with a laminate, as has been explained in connection with FIG. 3.

The summer insole can look exactly like the winter insole 65 shown in FIG. 5, although the cap is designed as a filling cap and is constructed with a non-warming spacer material of the type already mentioned.

FIG. 6 shows in a very schematic and not to scale representation a sectional view of part of the heat insulating cap 23 or the filler cap. The one adjacent to the slip opening is shown The area of the cap at the free end of which the transition lip 69 is fastened by means of a lip seam 77. Between the insertion-side edge of the cap and the insertion-side edge of the transition lip 69, the spring clip 71 is inserted, which by means of a zigzag seam 79 both on the cap and is attached to the transition lip 69. The Velcro fastener element 73 is located in the vicinity of the lip seam 77. Depending on whether it is the winter insole or the summer insole, the cap is with the air storage layer, preferably with the laminate described in connection with FIG. 3, or built with the non-warming spacer material.

FIG. 7 shows a blank 81 from which the heat insulation cap 23 or the filler cap is imaged. In the shoe tip area, the blank 81 is provided with a V-shaped gusset recess 83, which is sewn by means of the tension seam 67 to form the round tip of the toe on the shoe tip side. On both sides, the blank 81 is provided with a notch 85 for a bottom fold, which is located in FIG. 5 at the connection point between the insertion-side end of the cap and the circumference of the insole. In addition to the insertion-side end 87, the circumference of the blank 81 is sharpened in the edge region 89 in order to make it easier to attach the cap to the insole.

• 1) Luftspeicherndes Material 51:
     kompressionsresistenter Filz: Polyester-Vliesstoff;

  oder:

  poröses gesintertes Polyethylen ("Poroplast") anstelle oder zusätzlich zu dem kompressionsresistenten Filz;

  oder:

  offen- oder geschlossenporiger Kunststoffschaum.

• 2) Futtermaterialschicht 49:
     Wirkware mit einem Anteil von 72 Prozent Polyamid und 28 Prozent Polyester.
• 3) Funktionsschicht 53:
     mikroporöses Polytetrafluorethylen ("GORETEX").
• 4) Schutzschicht 55:
     Polyamid-Wirkware.
• 5) Füllkappenmaterial:
     Abstandsgestrick, Abstandsgewirke, Abstandsnetzmaterial.

Preferred materials for individual components of the heat insulation cap, the filler cap and the footwear according to the invention are now specified below.

• 1) Air-storing material 51:
  compression resistant felt: polyester nonwoven;

  or:

  porous sintered polyethylene ("Poroplast") instead of or in addition to the compression resistant felt;

  or:

  open or closed pore plastic foam.

• 2) Lining material layer 49:
  Knitted fabric with a share of 72 percent polyamide and 28 percent polyester.
• 3) Functional layer 53:
  microporous polytetrafluoroethylene ("GORETEX").
• 4) protective layer 55:
  Polyamide knitted fabric.
• 5) Filling cap material:
  Spacer knitted fabric, spacer fabrics, spacer mesh material.

The materials specified above represent only a preferred selection from possible materials.

Materials suitable for functional layer 53 include microporous stretched polytetrafluoroethylene (PTFE) as described in U.S. Patents 3,953,566 and 4,187,390; stretched PTFE provided with hydrophilic impregnating agents and / or layers as described in US Pat. No. 4,194,041; breathable polyurethane layers; or elastomers such as copolyether esters and their laminates as described in U.S. Patents 4,725,481 and 4,493,870.

Claims (32)

Heat insulation cap for lining the toe area of footwear (11; 63), the heat insulation cap (23) being constructed with an air-storing material (51) which has such a compression resistance that it is at compression pressures which occur during normal use of the footwear (11; 63) are exerted on the air-storing material (51), maintains air-storing capacity. Thermal insulation cap according to claim 1,
characterized by
that it is constructed with closed or open-pore plastic foam. Thermal insulation cap according to claim 1 or 2,
characterized by
that the thermal insulation cap is built up with felt. Thermal insulation cap according to claim 3,
characterized by
that the felt is formed by a polyester nonwoven. Thermal insulation cap according to one of claims 1 to 4,
characterized by
that it is provided with at least one waterproof, water vapor-permeable functional layer (53). Thermal insulation cap according to claim 5,
characterized by
that the functional layer (53) is built up with microporous polytetrafluoroethylene. Thermal insulation cap according to claim 5 or 6,
characterized by
that a functional layer (53) is arranged on the outside of the air-storing material (51) of the heat insulating cap (23) facing the upper (13) of the footwear (11; 63). Thermal insulation cap according to one of claims 5 to 7,
characterized by
that a functional layer (53) is arranged on the inside of the air-storing material (51) of the heat insulating cap (23) which points away from the shaft (13). Thermal insulation cap according to one of claims 1 to 8,
characterized by
that it is constructed with a laminate that has a waterproof, water vapor-permeable functional layer (53) on the outside facing the shaft (13), on the inside of the functional layer (53) pointing away from the shaft (13) a layer of air-storing material (51) and has a textile lining layer (49) on the side of the layer of air-storing material (51) which points away from the functional layer (53). Thermal insulation cap according to claim 9,
characterized by
that the laminate has a textile protective layer (55) for the functional layer (53) on the surface of the functional layer (53) facing the shaft (13). Thermal insulation cap according to claim 9 or 10,
characterized by
that the laminate has a second waterproof, water-vapor-permeable functional layer on the inside of the layer (51) of air-storing material pointing away from the shaft (13). Thermal insulation cap according to one of claims 1 to 8,
characterized by
that it is constructed with a laminate that has a layer of air-storing material (51) on the outside facing the shaft (13), and a waterproof, water-vapor-permeable functional layer () on the inside of the layer (51) of air-storing material pointing away from the shaft (13) 53) and has a textile lining layer (49) on the inside of the functional layer (53) which points away from the shaft (13). Thermal insulation cap according to one of claims 9 to 12,
characterized by
that the textile lining layer (49) consists of a knitted fabric constructed with polyamide and polyester. Footwear,
featured
by means of a thermal insulation cap (23) lining only its toe region according to one of claims 1 to 13. Footwear according to claim 14,
characterized by
that the thermal insulation cap (23) lines the toe area only of the upper material of the footwear (11; 63). Footwear according to claim 14,
characterized by
that the heat insulating cap (23) also lines the toe area of the sole structure of the footwear (11; 63). Footwear according to one of claims 14 to 16,
characterized by
that the heat insulating cap (23) is provided in addition to a shape stabilizing cap arranged in the toe area of the footwear (11; 63). Footwear according to one of claims 14 to 16,
characterized by
that the heat insulating cap (23) takes over the function of a shape stabilizing cap. Footwear according to one of claims 14 to 18,
characterized by
that the shaft (13) is constructed with a water- and air-permeable shaft material, that the shaft (13) and an insole (15) are lined on the inside with a sock-like insert, which is constructed with a waterproof, water-vapor-permeable functional layer, and that the heat insulating cap (23) is arranged on the inside of the toe area of the sock-like insert. Footwear according to one of claims 14 to 18,
characterized by
that the footwear (11; 63) is at least partially lined with a laminate lining (27) with a laminate structure according to one of claims 9 to 12 and that in the toe area of the footwear (11; 63) in addition to the laminate lining (27) a heat insulation cap (23 ) is arranged according to one of claims 9 to 12. Footwear according to claim 20,
characterized by
that the heat insulating cap (23) is arranged between the shaft (13) and the laminate lining (27). Footwear according to claim 20 or 21,
characterized by
that the heat insulation cap (23) is connected to the laminate lining (27) at its end region facing the heel region of the footwear (11; 63) via a transition web (35). Footwear according to claim 22,
characterized by
that the transition web (35) is connected at its one longitudinal edge (37) by means of a feed seam (39) to the laminate lining (27) and at its other longitudinal edge (41) by means of a cap seam (43) to the heat insulating cap (23). Footwear according to claim 23,
characterized by
that the lining seam (39) on the inside of the laminate lining (27) facing the interior of the footwear is watertightly sealed by means of a sweatband (59). Footwear according to one of claims 20 to 24,
characterized by
that the laminate lining (27) and the heat insulation cap (23) are tweaked around an insole (15) of the footwear (11; 63), that the lasting fold (47) of the heat insulation cap (23) is sharpened towards the free end in order to obtain a good fit and that approximately V-shaped gussets (45) are cut free in the gusset fold (47) of the heat insulating cap (23) from its peripheral edge in order to reduce the formation of folds in the gusset area. Removable winter insole for footwear,
characterized by
that a heat insulating cap (23) according to one of claims 1 to 13 is arranged on the toe region of the insole (65). Removable summer insole for footwear
characterized by
that on the toe area of the insole a filling cap with approximately the dimensions of the heat insulating cap of the winter insole according to claim 26 is arranged, which is constructed with an air and water vapor permeable, non-warming cushioning material, which at compression pressures at normal use of the footwear (63) provided with the insole can be exerted on the cushioning material, essentially maintaining its cushioning thickness. Summer insole according to claim 27,
characterized by
that the padding material of the filler cap is constructed with a mesh material, a spacer fabric or a spacer fabric. Insole according to one of claims 26 to 28,
characterized by
that the thermal insulation or the filler cap is provided with a spring clip (71) which keeps the slip-in end open at its slip-in end facing the heel region of the insole. Insole according to one of claims 26 to 29,
characterized by
that the heat insulation or the filling cap is provided on its insertion end facing the heel region of the insole with a wedge-shaped transition lip (69) serving as an insertion aid, the thickness of which decreases in the direction of the heel region of the insole. Insole according to one of claims 26 to 30,
characterized by
that the heat insulation or the filler cap is provided on its outside facing the shaft with a Velcro fastener element (73) which can be hooked up with a counter-Velcro fastener element at a corresponding point on the inside of a shoe upper. Footwear,
featured
by an insole according to one of claims 26 to 31.

Images