RU2045301C1 - Mask protecting breathing organs from cold - Google Patents

Abstract

FIELD: medical equipment. SUBSTANCE: mask has case 1 with hole 2 for inhalation and expiration and heat exchanger 3 which forms chamber 4 in case between case and hole 2 for inhalation and expiration. Hollow packing 5 manufactured from elastic material which heat conductivity is higher than that of material of case 1 is coupled to chamber 4. One or several holes 6 are made in bottom of hollow packing. EFFECT: improved quality of protection. 6 cl, 2 dwg

Description

 The invention relates to devices for protecting a person, namely, respiratory masks for protection against the cold.

Known breathing mask containing a housing made of a material with low thermal conductivity, in which a hole is made for inhalation and exhalation, a heat exchanger made of a material with high thermal conductivity, casing [1]
In this mask, the heat exchanger is placed outside its housing and is protected from the wind by a protective casing.

Known facial mask containing a housing made of a material with low thermal conductivity, in which a hole is made for inhalation and exhalation, a heat exchanger made of a material with high thermal conductivity and placed inside the housing [2]
In this mask, the heat exchanger heats the space between the double walls of the body to heat the face.

The closest analogue is a mask to protect the respiratory organs from cold, comprising a housing made of a material with low thermal conductivity, in which an opening for inspiration and expiration is made, a heat exchanger made of a material with high thermal conductivity and placed inside the housing, the side walls of the heat exchanger being connected to the housing [3]
The disadvantage of this mask is the formation in the heat exchanger of the frozen condensate of water vapor released by a person during breathing, in the form of ice, frost, as a result of which the openings of the heat exchanger become clogged, increasing the resistance to inhalation-exhalation.

 The technical task is to increase the time of continuous stay in the cold of a person, increase the range of negative temperatures, provide the ability to quickly remove frozen condensate of exhaled water vapor by making it possible to achieve positive temperatures at the inlet-outlet of the heat exchanger at lower ambient temperatures, reduce the overall dimensions of the heat exchanger and condensed moisture in the front space of the mask body.

 The problem is solved in that in a mask for protecting respiratory organs from cold, comprising a body made of a material with low thermal conductivity, in which an opening for inspiration and expiration is made, a heat exchanger made of a material with high thermal conductivity and placed inside the body, the side walls of the heat exchanger connected to the body, the walls of the body form a chamber between the heat exchanger and the opening for inspiration and expiration, to which through the opening for inspiration and expiration a hollow nozzle made of elastic m a material whose thermal conductivity is higher than the thermal conductivity of the body material, and one or more holes are made in the bottom of the hollow nozzle.

 In addition, a nozzle is connected to the hole of the bottom of the hollow nozzle, the longitudinal axis of which intersects the longitudinal axis of the hole of the bottom of the hollow nozzle, and the nozzle is made of elastic material.

 In one embodiment, the hollow nozzle with nozzle may be mounted to rotate around the axis of the hole for inspiration and expiration.

 In another embodiment, the side walls of the heat exchanger may be connected to the housing via a partition.

 In addition, the heat exchanger can be made in the form of a metal corrugated tape rolled into a spiral.

 The heat exchanger can also be made of metal mesh or several metal tubes.

 In FIG. 1 shows a longitudinal section of a mask; in FIG. 2 one of the design options of the heat exchanger, cross section.

 The mask for protecting respiratory organs from cold contains a housing 1 made of a material with low thermal conductivity. In the housing 1, a hole 2 is made for inhalation and exhalation. The heat exchanger 3 is made of a material with high thermal conductivity and is installed inside the housing 1, while the side walls of the heat exchanger 3 are connected to the housing 1. The walls of the housing 1 form a chamber 4 between the heat exchanger 3 and the opening 2 for inhalation and exhalation. A hollow nozzle 5, made of an elastic material, the thermal conductivity of which is higher than the thermal conductivity of the material of the housing 1, is connected to the chamber 4 through the hole 2. One or more holes 6 are made in the bottom of the hollow nozzle 5.

 A nozzle 7 is connected to the hole 6 of the bottom of the hollow nozzle 5, the longitudinal axis of which intersects the longitudinal axis of the holes 6. The nozzle 7 is also made of elastic material, as is the hollow nozzle 5. The hollow nozzle 5 with the nozzle 7 can be mounted to rotate around the axis of the hole 2 for inhalation and exhalation, for which the hollow nozzle 5 can be fixed in the hole 2 with the appropriate interference or flanging can be performed on it. The heat exchanger 3 can be directly connected to the walls of the housing 1 or the side walls of the heat exchanger 3 can be connected to the housing 1 by means of a partition 8 (see Fig. 1). The heat exchanger 3 can be made in the form of a metal corrugated tape 9, rolled into a spiral, or from a metal mesh.

Hollow nozzle 5 allows you to implement several functions in the mask device. Firstly, it is an additional heat-reflecting screen when exhaling. Second, the thermal conductivity of the material of the hollow nozzle 5 is chosen so that, taking into account the thermal conductivity of the body 1 and the thermal conductivity and heat capacity of the heat exchanger 3 to obtain at the interface connection between the camera 4 with a hollow nozzle 5 the temperature below 0 ^{° C,} starting from the lowest ambient operating temperature. Thirdly, the hollow nozzle 5 serves as a respiratory vapor condenser; it is in the hollow nozzle 5 that the condensed vapor crystallizes. To fulfill these conditions, the thermal conductivity of the material of the hollow nozzle 5 is selected above the thermal conductivity of the material of the housing 1.

Depending on the specific materials used in the housing 1, thermal conductivity and heat capacity of the heat exchanger 3, the physicomechanical characteristics of the material of the hollow nozzle 5 can be calculated or experimentally selected. Such material may be rubber or synthetic elastic materials. By appropriately selecting the dimensions of the hollow nozzle 5, the diameter of the holes 2 for inhalation and exhalation, the housing material 1, heat exchanger 3 manages guaranteed to get a positive value of the temperature in the chamber 4 at ambient temperatures of 70 ^{° C} and below, and thus the crystallization of moisture condensed exhaled vapor will always occur in hollow nozzle 5.

 Fourth, due to the fact that the hollow nozzle 5 is made elastic, it is possible to efficiently and quickly remove frozen condensate from it.

 The heat exchanger 3 can be directly connected by the side walls to the housing 1, for which the profile of the heat exchanger 3 can repeat the profile of the housing 1 in such a way as to form a chamber 4. In addition, the side walls of the heat exchanger 3 can be connected to the housing 1 by means of a partition 8. Moreover, the partition 8 can be made both of a material with high thermal conductivity, then it behaves like an additional "heat exchanger", so of a material with low thermal conductivity, then it behaves like a heat shield.

 Since the heat exchanger 3 is located inside the housing 1 and its surface does not contact directly with the environment, and also due to the introduction of an additional hollow nozzle 5, the dimensions of the heat exchanger can be reduced, which leads to a decrease in the consumption of metals during production. The number and size of holes 6 of the bottom of the hollow nozzle 5 are selected so as to provide easy removal of the crystallized products of condensed moisture and not create significant resistance to breathing.

 The nozzle 7 can be located at right angles to the vertical position of the person, but it can additionally be rotated together with the nozzle 5 in the direction opposite to the direction of the wind, therefore the nozzle 7 protects more effectively from the oncoming and lateral directions of the winds. In addition, an increase in temperature in the front space of the mask body 1 reduces the amount of condensed expired moisture in the contact zone of the body 1 with a person’s face.

 The housing 1 of the device can be made of a material with high heat-insulating properties, for example, polyethylene foam, porous rubber, etc.

 The tape 9 of the heat exchanger 3 can be made of steel, non-ferrous metals and other materials with high thermal conductivity and heat capacity.

 The mask works as follows.

 It is worn (see Fig. 1), tightly closing the respiratory system with body 1. When a person exhales air, the heat exchanger 3 heats up. Since the air temperature in the chamber 4 is positive, moisture vapor formed during breathing enters the hollow nozzle 5, where moisture condenses and crystallizes at low negative ambient temperatures. If breathing is difficult due to moisture crystallization, the hollow nozzle 5 is crimped by hand, and since it is elastic, crumbling and breaking of relatively large particles of ice occurs. Then the person makes a sharp forced expiration and crystallization products are removed from the hollow nozzle 5.

 With a unilateral wind direction, the nozzle 7 together with the hollow nozzle 5 is rotated so that the hole of the nozzle 7 is directed in the opposite direction to the wind direction. When the wind is variable, the pipe 7 can be directed towards the human chest.

 The mask to protect the respiratory organs from the cold can be used to work in the winter conditions of the Far North, Antarctica, in the highlands, and can be widely used by construction workers, hunters, climbers, and geologists.

Claims (6)

 1. MASK FOR PROTECTION OF RESPIRATORY BODIES FROM THE COLD, comprising a body made of a material with low thermal conductivity, in which an opening for inhalation and exhalation is made, a heat exchanger made of a material with high thermal conductivity and placed inside the body, the side walls of the heat exchanger connected to the body, characterized in that the chamber walls are formed between the heat exchanger and the inhalation and exhalation opening, to which a hollow nozzle made of an elastic mat is connected through the inhalation and exhalation opening rial, whose thermal conductivity is higher than the thermal conductivity of the housing material and the one or more openings formed in the bottom of the hollow tip.  2. The mask according to claim 1, characterized in that a nozzle is connected to the holes of the bottom of the hollow nozzle, the longitudinal axis of which intersects the longitudinal axis of the holes, and the nozzle is made of elastic material.  3. The mask according to claims 1 and 2, characterized in that the hollow nozzle with the nozzle is mounted with the possibility of rotation around the axis of the hole for inhalation and exhalation.  4. The mask according to any one of claims 1 to 3, characterized in that the side walls of the heat exchanger are connected to the housing by means of a partition.  5. The mask according to any one of claims 1 to 4, characterized in that the heat exchanger is made in the form of a metal corrugated tape rolled into a spiral.  6. The mask according to any one of claims 1 to 4, characterized in that the heat exchanger is made of a metal mesh or several metal tubes.