RU74563U1 - HYPOTHERM APPLICATOR - Google Patents

Abstract

1. The applicator for hypothermia, containing two sealed shells interconnected and forming a cavity in communication with pipes for supplying and discharging liquid refrigerant, the shells being interconnected by partitions forming flow channels for the refrigerant, the partitions are curved along the direction of flow of the refrigerant, and the outer surface of one of the shells is covered by a heat-insulating casing. 2. The applicator according to claim 1, characterized in that the partitions are composed of separate sections. The applicator according to claim 1 or 2, characterized in that the partitions are made wavy. The applicator according to claim 1, characterized in that in the casing there are sealed cavities communicated with a pipe for supplying compressed gas of low pressure. The applicator according to claim 1, characterized in that the outer surface of the other shell facing the cooled area of the body is covered with a capillary-porous body impregnated with a liquid.

Description

The invention relates to medical equipment, namely, to devices for local cooling of individual parts of the body.

The device can be used in the treatment of diseases of the musculoskeletal system, in particular, rheumatoid arthritis, in arthrology, in the treatment of neurological diseases, inflammatory processes.

A number of devices for local tissue freezing are known, for example, portable cryoapplicators (EP 05070301). This and similar devices operate on liquid nitrogen, which, mixed with air or other gas in mixers of various designs, allows you to cool various parts of the body. This and similar devices are equipped with a cold flow control system, as well as a temperature sensor for the cold gas stream. The disadvantage of liquid nitrogen apparatuses is that a high cooling rate and a high temperature difference make it difficult to measure the true temperature of the tissue being cooled, which makes automation of cryogenic control impossible. The difference between the proposed technical solution and the well-known one is that direct contact of the coolant with the fabric being cooled is prevented and cold is saved due to the reuse of the used refrigerant during recycling.

Also known is the “DigniKep” apparatus of DigniTana (Shevelev O.A., Byakhov M.Yu. Medical file, 2006, v.106, No. 11, pp. 16-18 or US 6156059) for cooling a human scalp in order to prevent alopecia of patients, receiving chemotherapy. This unit is equipped with a hard cast silicone helmet-applicator, inside of which the coolant circulates. A disadvantage of the known technical solution is that in some cases the uniformity of cooling is not provided. This leads to uneven effects of cold on the scalp and

to uneven hair loss. In addition, there is the impossibility of using the applicator itself for cryotherapy on other parts of the body.

The first objective of the proposed technical solution is to increase the uniformity of cooling of body parts.

The second task is to expand the scope, in particular, providing the possibility of using the applicator to cool various parts of the body.

The tasks are solved in that the applicator for hypothermia contains two sealed shells connected to each other and forming a cavity in communication with pipes for supplying and discharging liquid refrigerant, and the shells are connected by partitions forming flow channels for the refrigerant, the partitions are made curved, in particular , wavy, along the direction of flow of the refrigerant, and the outer surface of one of the shells is closed by a heat insulating casing. Partitions can consist of separate sections. In the casing can be made sealed cavity in communication with the pipe for supplying compressed gas of low pressure. The outer surface of the shell facing the cooled portion of the body may be coated with a capillary-porous body impregnated with a liquid with high thermal conductivity.

The tasks are solved by the following design features. Partitions distribute the flow of coolant over the surface of the shell and prevent the loss of the geometric shape of the shells under the influence of internal pressure. In this case, the structural rigidity is reduced, and the abutment density of the applicator to the body is increased due to the fact that the partitions are made curved, in particular, wavy. A capillary-porous body containing a liquid further increases the uniformity of heat dissipation. The tight cavities of the heat-insulating casing when filled with compressed gas from a source of low pressure provide more tight contact and pressing of the applicator to the cooled area of the body, which allows even better

uniform heat dissipation. Additionally, the stiffness of the applicator decreases when the partitions are made in the form of separate sections, which allows it to be used for body sections with a high curvature of the surface.

Brief Description of the Drawings

Figure 1 presents a General view of the applicator.

Figure 2 presents a General view of the applicator in accordance with the preferred embodiment.

Detailed Description of Drawings

Figure 1 presents a General view of the applicator.

Applicator 1 has the following design. The elastic shells 5 are interconnected by partitions 6 with the formation of a sealed inner cavity 3, which is a network of flow channels covering the entire, or almost the entire area of the shells. The internal cavity 3 is connected to the source and receiver of the refrigerant by means of the inlet pipe 2 and the outlet pipe 4. The partitions 6 are made of elastic material and have a curved, in particular, wavy, shape along the direction of flow of the refrigerant and can be either solid or separate sections (as shown in figure 2). The elastic shell 5 facing the cooled portion of the body is covered with a capillary-porous body 7 impregnated with a liquid. Another elastic shell 5 of the applicator is closed by a heat-insulating casing 8, inside of which there are sealed cavities 9 filled with gas, which are connected to a source of compressed gas of low pressure using a pipe 10.

The device operates as follows. The applicator 1 is applied to the cooled area with a capillary-porous body 7 and fixed to the body using known means. To ensure a more dense and uniform fit into the sealed cavity 9 of the heat-insulating casing 8 through the pipe 10 serves compressed

gas. The heat-insulating casing 8 provides a reduction in the intensity of heat transfer between the refrigerant and the environment. The liquid refrigerant from the source of refrigerant is pumped to the internal cavity 3 of the applicator 1 through the inlet pipe 2. In this case, thermal energy is transferred from the cooled portion of the body, first the heat-conducting fluid impregnating the capillary-porous body 7, and then through the elastic sheath 5 is removed by the flow of refrigerant , which passes through the network of channels in the cavity 3 and, after the heat transfer is completed, is removed from the cavity 3 through the outlet pipe 4 and then returns to the source of refrigerant. As the liquid refrigerant, any suitable liquid can be used which does not freeze at the required temperature, in particular a 50% aqueous solution of ethylene glycol.

Claims (5)

1. The applicator for hypothermia, containing two sealed shells connected to each other and forming a cavity in communication with the nozzles for supplying and discharging liquid refrigerant, and the shells are interconnected by partitions forming flow channels for the refrigerant, the partitions are made curved along the direction of flow of the refrigerant, and the outer surface of one of the shells is closed by a heat-insulating casing. 2. The applicator according to claim 1, characterized in that the partitions are composed of separate sections. 3. The applicator according to claim 1 or 2, characterized in that the partitions are made wavy. 4. The applicator according to claim 1, characterized in that in the casing there are sealed cavities communicated with a pipe for supplying low pressure compressed gas. 5. The applicator according to claim 1, characterized in that the outer surface of the other shell facing the cooled area of the body is covered with a capillary-porous body impregnated with a liquid.