RU166900U1 - ELECTRIC CONVECTION PHYTOPAROGENERATOR TYPE - Google Patents

Abstract

1. An electric convection-type phytoparogenerator comprising a convection casing, a heating section installed therein, including a heat source enclosed by a metal casing, and evaporator platinum guides cascaded to the outer side surface of the heating section, characterized in that it is further provided with at least , with one heating section and a container for receiving a phyto-solution, while the heating sections are equipped with electric heating elements, evaporator plates are installed between the heating sections a, a container positioned above the heating section to supply on-phytosolutions ispariteli.2 plate. The phyto-steam generator according to claim 1, characterized in that a tubular electric heating element is used as the electric heating element. 3. The phyto-steam generator according to claim 1, characterized in that the container for receiving the phyto-solution is provided with a lid, a metered-solution phyto-solution feed device and a grid, the cells of which are configured to hold particles of the plant material to be steamed. The phyto-steam generator according to claim 3, characterized in that the container for receiving the phyto-solution and its lid are made of stainless steel. 5. The phyto-steam generator according to claim 1, characterized in that it is equipped with a funnel for receiving the phyto-solution and its supply to the evaporator plates. 6. The phyto-steam generator according to claim 1, characterized in that the convection openings are located on the front surface of the convection casing below the bottom of the container. The phyto-steam generator according to claim 1, characterized in that the convection openings are provided with shutters configured to change the air flow rate. Phyto-steam generator according to claim 1,

Description

The utility model relates to the field of steam generation, namely, to steam generating devices with electric heating and can be used to obtain finely dispersed steam saturated with active phyto-substances in steam rooms of various sizes, including small sizes, not more than 3.5 m ³ , for example, in the bathroom of an apartment building.

Known furnace for a bath in which an electric heating element is used as a heat source, located in the lower part of the metal casing under the heater capacity, commensurate with the surface of the furnace. The stones are heated by heat exchange with the hot surface of the furnace. To generate steam, portions of water are fed onto the surface of heated stones (see patent RU No. 13688, F24C 7/00, 2000).

The disadvantages of this solution are the long process of heating the stones; low specific steam capacity; the production of coarse steam, which impairs the healing properties of the steam room microclimate; the large sizes necessary to obtain a sufficient amount of steam, limited functionality, requiring the installation of additional equipment to obtain a phyto-solution, which is inconvenient to maintain and excludes the possibility of its use in paired rooms of small sizes not exceeding 3.5 m ³ .

Known steam generator, made in the form of metal chambers of water evaporation, formed by the surfaces of the walls, heated to a temperature not lower than the boiling point of water, located between them closed on top of the perforated wall of the electric heating element, and fixed to the walls of the evaporator elements, located one above the other the formation of the compartments of the chambers and made with holes that allow the flow of water from the upper compartment to the lower one, placed in a housing closed by a protective mesh equipped with a water tank with a dispenser installed above, separated from it by a screen with holes for water flow, forming a niche with a protective net and a protective-decorative convector with a window for steam output, equipped with a carrier panel made with the possibility of attaching a housing to it, a tank for water and protective and decorative convector (see patent RU 87912, АНН 33/06, F24C 13/00, 2009).

However, this solution is not without drawbacks. The device has an underdeveloped heat transfer area, from which water evaporates. Indeed, only an insignificant part of heated metal vapor-forming surfaces works on evaporation, and the rest of them practically only contributes to the long-term retention of heat. The heat transfer rate and heat removal efficiency are reduced. In addition, there are obstacles to the free passage through the profile elements of convection flows. The vapor obtained in the form of a saturated cloud quickly mixes with the air mass, without creating the necessary conditions. Evaporated water lingers for a long time in compartments and the steam is wet and heavy. The process of steaming plant materials, laid on a protective grid, with water vapor coming from the evaporation chambers to dry plants, reduces the intensity of its saturation with useful substances, prevents the preservation of the entire complex of active substances in their natural forms. It is possible for particles of steaming plant material to slip through a protective mesh onto a heated surface. Problems with the replacement of heating elements are not ruled out. Inadequate heating of the water in the tank also affects the quality of the steam.

A well-known domed vaulted bell furnace with a built-in steel steam generator, comprising a convector casing with convection openings, a combustion chamber installed in it with a heat source located therein and inclined guide metal plates-evaporators fixed to the outer wall of the combustion chamber installed between the wall of the combustion chamber and external wall, steps alternating with each other with various slopes, with gaps between them. The steam generator is equipped with a solid fuel heating source. Has a developed heat transfer surface. Provides the production of finely dispersed steam and intensive circulation of finely dispersed vapor-air mixture. Allows you to create a bath steam condition when using a broom massage or other procedure with maintaining the humidity necessary for soaking in a steam room for a long time (see patent RU 142846, F24C 1/00, 2014). This solution is the closest analogue of the claimed utility model and is taken as a prototype.

The disadvantages of this solution are the presence of a solid fuel heat source, limiting the possibility of placement, for example, in a multi-unit housing stock, cumbersome and limited functionality. To obtain a phyto-solution, additional equipment is required, which cannot be placed in paired rooms of small sizes, and if there are appropriate sizes of a paired room for its placement, it is inconvenient to maintain. This limits the possibility of creating individual microclimates of inhalation-steam bath conditions for increased health effects on the human body in paired rooms of various sizes, especially small ones, of no more than 3.5 m ³ , for example, in the bathroom of an apartment building.

The task the utility model is aimed at is improving the healing and healing effects of inhalation-steam bath procedures while expanding the possibility of them being carried out in steam rooms of various sizes, even small ones, for example, in the bathroom of an apartment building, the volume of which is no more than 3.5 m ^3, without the use of bulky equipment through the creation of a simple and convenient in operation of the compact electric apparatus - fitoparogeneratora having smaller dimensions and simultaneously races Irene functionality.

The technical result that can be obtained by implementing the utility model is the possibility of high-performance production of finely dispersed phytocouple — finely dispersed vapor saturated with active substances from photographic material, with the compact size of the device itself.

The essence of the utility model is that in an electric convection-type phyto-steam generator containing a convection casing, a heating section installed in it, including a heat source enclosed by a metal casing and guiding platinum evaporators cascaded to the outer side surface of the heating section, the feature is the fact that it is additionally equipped with at least one heating section and a container for receiving phyto-solution, while the heating sections are equipped with electric heating elements, evaporator plates are installed between the heating sections, and a container is installed above the heating sections with the possibility of feeding phyto-solution to the evaporator plates. In addition, a tubular electric heating element is predominantly used as the electric heating element. The container for obtaining a phyto-solution is preferably provided with a lid, a phased-in phyto-solution feed device and a grid, the cells of which are configured to hold particles of the plant material to be steamed. In this case, the container for receiving the phyto-solution and its lid are preferably made of stainless steel. The phyto-steam generator is preferably provided with a funnel for receiving the phyto-solution and supplying it to the evaporator plates. Convection openings are expediently located on the front surface of the convection casing below the bottom of the container. They can be equipped with shutters configured to change the air flow rate. The convection casing, the container for receiving the phyto-solution, the receiving funnel, the casing of the heating sections, the evaporator plates are preferably made of stainless steel. The peculiarity lies in the fact that for any specified embodiment of the device, the evaporator plates can be located with different slopes with gaps between them. These essential features in the aggregate ensure the achievement of the specified technical result.

The technical means with the claimed sets of essential features are unknown from the prior art, which confirms its compliance with the patentability condition - novelty.

The essence of the utility model is illustrated by images. In FIG. 1 shows a phyto-steam generator in a perspective view, a general view from the left; in FIG. 2 - phytoparogenerator in a perspective view, general view on the right; in FIG. 3 is the same as in FIG. 1 with an open end to the left; in FIG. 4 is the same as in FIG. 2 with an open end to the right; in FIG. 5 is the same as in FIG. 1 with an open heating section; in FIG. 6 - presents an evaporation chamber with a tray; in FIG. 7 - a perspective view of the evaporation chamber with a cut side surface, inside view; in FIG. 8 shows a fragment of a container for a phyto-solution with a grid, inside view; Fig. 9 shows a phyto-steam generator in a perspective view, a general rear view; in FIG. 10 is a table, and FIG. 11, 12 are graphs showing the results of tests of an electric convection type phyto-steam generator. An electric convection-type phytoparogenerator (hereinafter referred to as a phytoparogenerator) contains a convection casing 1 with convection openings 2, in which heating sections 3 are installed, formed between the heating sections 3 of the evaporation chamber 4, and a container 5 located above them for receiving a phyto-solution. The heating sections 3 with evaporation chambers 4 together represent a steam-generating unit (not indicated), which is fixed by the ends on the inner surfaces of the end walls 6, 7 of the convection casing 1. Between the convection casing 1 and the steam-generating unit there is a sufficient space for the passage of air convection flow. Each heating section 3 is made in the form of a heat source enclosed by a metal casing 8, which is used as an electric heating element 9, for example, a tubular electric heater (TEN). This does not exclude the possibility of using other types of electric heating elements 9 of any known design. The number of heating sections 3 can be different, but not less than two, i.e. multi-sectional execution of a steam generating unit is possible. Between the outer side surfaces of each adjacent heating sections 3 are cascaded with the possibility of passage of the phyto-solution from top to bottom the guide plates-evaporators 10, where it is formed along the evaporation chamber 4. The plates-evaporators 10 can be arranged with different slopes with gaps between them. The number of evaporation chambers 4 is determined by the number of heating sections 3 and depends on the size of the twin room. The container 5 is equipped with a lid 11, the dispenser 12 - a device for dosed supply of phyto-solution to the evaporator plates 10 and a fine mesh 13, the mesh size of which prevents particles of the plant material being steamed into the dispenser 12. The volume of the container 5 is at least 10 l, which corresponds to the amount of the phyto-solution sufficient for one hour of inhalation-steam bathing procedures. The evaporation chamber 4 in the upper part is equipped with a funnel 14 for receiving phyto-solution, which is oriented under the dispenser 12. Under the evaporation chamber 4 in the lower part of the device there is a tray 15 for collecting non-evaporated phyto-solution. For this, the bottom plate-evaporator 10 is installed with a slope in the pan 15. Between the convection hood 1 and the pallet 15 there is a gap 16 for air flow, which allows you to create an upward air flow in the space between the steam generating unit and the convection hood 1. Convection openings 2 are made on the front surface convection casing 1 below the level of the bottom of the tank 5 for the exit of heated air and the phytocouple from the phyto-steam generator into the steam room. Convection openings 2 are provided with flaps (not shown), which provide the possibility of changing the flow rate of the heated air and phytocouple. The end walls 6, 7 of the convection casing 1 are removable for the implementation of service and repair procedures. Outside, on the end wall 17 of the evaporation chamber 3, a terminal box 18 and, located above it, a heating controller 19 are fixed. Convection casing 1 is equipped with mounting brackets (not shown) for mounting the phyto-steam generator on the wall of the room for bath procedures. Installation of a phyto-steam generator on the floor is possible. The shape of the convection casing 1 repeats the shape of the steam generating unit and container 4 installed in it. The convection casing 1, the casing 8 of the heating sections 3, the evaporator plates 10, the container 5, the lid 11, the funnel 14, the pallet 15 are made of stainless steel. The execution of stainless steel allows to reduce the wall thickness, which provides better heating with smaller dimensions of the product. Various modifications of the device are possible. Phytoparogen works as follows.

The phyto-steam generator is installed on the wall of the room for inhalation-steam bathing procedures through mounting brackets. Before carrying out inhalation-steam bathing procedures, water is poured into a container 5 and photo material is placed (bath brooms, or phyto-collections or other plant material). The container 5 is covered with a lid 11 to prevent the phyto-solution from evaporating from it when heated. By means of the heating controller 19, electric heating elements 9 are turned on, which heat the bottom of the tank 5, evaporator plates 10 and air between the steam generating unit and the convector casing 1. Thus, convection heating of the steam room is created, which is formed by a heated upward air flow that enters the phyto-steam generator through the gap 16 and goes into the steam room through the convection openings 2. At the same time, the convection casing 1 shields the hard thermal radiation from the steam generating unit, which effectiveness to the uniform distribution of heat in the room doubles and uniform heating of the human body, which has beneficial effects on the healing properties of the pair indoor climate. After preparing the phyto-solution and reaching the set temperature of the steam room from 50 to 80 ° C, open the dispenser 12 to create constant evaporation in the evaporation chamber 4 with a given intensity. After the dispenser 12 is opened from the container 5, the hot phyto-solution filtered by the grid 13 enters the funnel 14, from which it passes from top to bottom along the hot plates-evaporators 10, where the phyto-solution is converted into a finely dispersed phyto-pair. The supply of already hot phyto-solution to the evaporator plates 10 improves the quality of the phytocouple. The higher the temperature of the phyto-solution to obtain a phytocouple, the better the phytocouple itself. The continuous supply of phyto-solution to the evaporator plates 10 ensures the continuous generation of finely dispersed phytocouple. The increased path of the phyto-solution along the surfaces of the evaporator plates 10 increases the heat transfer surface and, therefore, increases the heat transfer. An unevaporated phyto-solution flows into the pallet 15. The resulting finely dispersed phytocouple is mixed in the space between the steam-generating unit and the convection casing 1 with the air convection flow entering through the gap 16, and a phyto-vapor mixture is formed, which enters the steam room through the convection openings 2. The phytopath entering the steam room the mixture creates a healing microclimate that has a healing effect on the human body. The constant heating of the container 5 due to contact with the steam generating unit and heated air allows to improve the extraction of photographic material, increase the productivity of the device and reduce its size.

To complete the inhalation-steam procedure by means of the regulator 19, the electric heating elements 9 are turned off and the processes of vaporization and heat exchange are stopped. The unevaporated phyto-solution collected in pan 15 is poured.

The test results of the phyto-steam generator (FIG) are shown in the table (Fig. 10), in graphs 1 and 2 (Figs. 11 and 12). When testing the phyto-steam generator, it was possible to achieve the result of obtaining procedures within 45 minutes after turning on the device. Getting stable finely dispersed steam saturated with active substances and aromas of herbs, you can, without fear of overheating, stay indoors for a long time (temperature from 55 to 68 ° C and air humidity of 35-37%), which is required by the recommendations of inhalation procedures ( within 20 minutes). Conventional electric heaters heat the stone for at least 120 minutes to obtain finely dispersed steam and during this time the room (cabin) warms up to temperatures of 100 ° C and higher, so humidity in such rooms does not require inhalation procedures and being in such modes is not safe for some people with various forms of disease. But a healthy person can be in such modes for several minutes, which is not suitable for inhalation procedures.

The compact size of the phyto-steam generator, adjustable power, easy controllability, safety make it possible not only to easily place it even in small twin rooms, but also to create optimal conditions with a given microclimate in them with the help of a single device for making full bath, including steam, inhalation , massage procedures with increased healing effects on the human body.

The described means and methods by which it is possible to implement the claimed technical solution of an electric convection type phytoparogenerator with the implementation of this purpose confirm the compliance of the claimed utility model with the patentability condition - industrial applicability.

Claims (9)

1. An electric convection-type phytoparogenerator comprising a convection casing, a heating section installed therein, including a heat source enclosed by a metal casing, and evaporator platinum guides cascaded to the outer side surface of the heating section, characterized in that it is further provided with at least , with one heating section and a container for receiving a phyto-solution, while the heating sections are equipped with electric heating elements, evaporator plates are installed between the heating sections a, a container positioned above the heating section to supply phytosolutions on-plate evaporators. 2. The phyto-steam generator according to claim 1, characterized in that a tubular electric heating element is used as the electric heating element. 3. The phyto-steam generator according to claim 1, characterized in that the container for receiving the phyto-solution is provided with a lid, a device for dosed supply of the phyto-solution and a grid, the cells of which are configured to hold particles of the plant material being steamed. 4. The phyto-steam generator according to claim 3, characterized in that the container for receiving the phyto-solution and its lid are made of stainless steel. 5. The phyto-steam generator according to claim 1, characterized in that it is equipped with a funnel for receiving the phyto-solution and its supply to the evaporator plates. 6. The phyto-steam generator according to claim 1, characterized in that the convection openings are located on the front surface of the convection casing below the bottom of the container. 7. The phyto-steam generator according to claim 1, characterized in that the convection openings are provided with shutters configured to change the air flow rate. 8. The phyto-steam generator according to claim 1, characterized in that the convection casing, the container for receiving the phyto-solution, the receiving funnel, the casing of the heating sections, the evaporator plates are made of stainless steel. 9. The phyto-steam generator according to claim 1, or 2, or 3, or 4, or 5, or 6, or 7, or 8, characterized in that the evaporator plates are arranged with different slopes with gaps between them.

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