WO2013191584A1 - Electric heating furnace for saunas and banyas - Google Patents

Description

 Electric heating stove for saunas and baths

Technical field

 The utility model relates to designs of electric heating furnaces and can be used, in particular, for equipping individual baths and saunas, rural baths, urban baths, baths or saunas in sports and recreation complexes to create a certain temperature and humidity regime in them.

State of the art

An electric heating furnace for baths and saunas is known from the prior art, comprising a housing with at least one electric heating element disposed therein, configured to permit the passage of heated air (see, for example, DE3311849A1, publ. 06.10.1983). The disadvantage of this technical solution is the lack of insulation of the heated air from the electric heating element, which leads to the burnout of organic substances and oxygen in the heated air with the release of harmful substances, which adversely affects human health and causes the appearance of an unpleasant odor in a bath or sauna.

Also known from the prior art is an electric heating furnace for saunas and baths, including a housing with main and 5 additional electric heating elements located therein and a water injection system for vaporization from the surface (see, for example, DE3151 147A1, published on 07.28.1983 ) The disadvantage of this technical solution is the lack of complete isolation of the heated air from the electric heating element, as well as the lack of isolation of water intended for vaporization from additional electric heating elements, which indicates insufficient reliability and safety of the device.

The closest in technical essence to the claimed technical solution is an electric heating furnace for saunas and baths, including

15 case with placed in it at least one electric heating element, made with the possibility of passing heated air with its simultaneous isolation from the electric heating element (see, for example, RU45014, publ. 10.04.2005). The disadvantage of this technical solution is the lack of a water intake system and its distribution according to

20 surfaces of the body of the electric heating furnace, which does not provide convenience when regulating the humidity of the heated air in the premises of the bath or sauna.

Disclosure of invention

The task to which this technical solution is directed, 25 is to increase the reliability and safety of the device.

The problem is solved due to the fact that in the electric heating furnace for saunas and baths, which includes a housing with at least one electric heating element located in it, made with the possibility of allowing heated air to pass through while isolating it from the electric heating element, according to the technical solution , the housing includes at least one upper evaporator and at least one vertical evaporator configured to receive and distribution of water intended for vaporization from their surface, with its simultaneous isolation from the electric heating element.

 The upper and vertical evaporators can be made with grooves and calibrated channels for receiving and distributing water on the surfaces of 5 evaporators with the exception of water entering electric heating elements.

The furnace body may be made of a material having high thermal conductivity, heat capacity and heat resistance.

 The furnace body can be made of natural material with high thermal conductivity, heat capacity and heat resistance.

 Talcochlorite, or talc magnesite, or talcocarbonate can be used as a natural material.

 The upper and vertical evaporators are made of talc chlorite, or talc magnesite, or talcocarbonate.

 15 Channel-forming elements can be placed in the furnace body, made with the possibility of passing heated air with its simultaneous isolation from the electric heating element.

 As channel-forming elements, ceramic and / or chamotte pipes, or pipes made of heat-resistant concrete, can be used.

 20 Hollow ceramic and / or chamotte slabs and / or heat-resistant concrete slabs can be used as channel-forming elements.

 As channel-forming elements, at least two slabs of talc chloride, talc magnesite, or talc carbonate, or heat-resistant concrete can be used.

 25 As channel-forming elements, plates of heat-resistant heat-insulating material with longitudinal ribs made on them can be used.

A plate of heat-resistant heat-insulating material can be oriented in such a way that its longitudinal ribs are directed in the opposite direction from the electric heating element. A plate of heat-resistant heat-insulating material can be oriented in such a way that its longitudinal ribs are directed towards the electric heating element, closed by a plate made of talc chloride, talc magnesite, talc carbonate, chamotte or heat-resistant 5 concrete.

A plate of heat-resistant heat-insulating material can be oriented in such a way that its longitudinal ribs are directed towards the longitudinal ribs of another heat-insulating plate with the formation of channels.

 The channel-forming elements may be provided with a fan or connected to it.

Housing elements and channel-forming elements can be connected by means of metal studs and / or bolted fasteners.

 Housing elements can be connected by means of metal studs and / or bolted fasteners.

 15 Housing elements can be connected by means of metal studs and / or bolted fasteners, at least some of which are equipped with heat-resistant rings.

 The electric heating element may be equipped with a thermal fuse.

20 The furnace may be optionally equipped with or associated with a temperature controller.

 The temperature controller can be made in the form of an electronic controller.

 The temperature controller can be made in the form of a gauge 25 sensor.

 The temperature controller can be made in the form of a bimetallic plate.

 The furnace may be further provided with a water injection system.

The furnace may be further provided with a switching device, made with the possibility of providing parallel or serial connection to at least two sources of electricity. S

The housing may be provided with at least one heat reflector to enhance the heat flux from the electric heating elements towards the vertical evaporator.

Ceramic or chamotte plates, or plates made of heat-resistant concrete, can be selected as a heat reflector.

The surface of the housing elements, including the upper and vertical evaporators, may be roughened.

The technical result provided by the given set of features is to increase the reliability and safety of the device due to the implementation of the upper and vertical evaporators with the possibility of receiving and distributing water intended for vaporization from their surface, with its simultaneous isolation from the electric heating element.

In addition, the implementation of the housing of an electric heating furnace for saunas and baths with the possibility of allowing heated air to pass through while being isolated from the electric heating element allows heated air to be obtained with a sufficient degree of humidity and temperature, with the exception of burning of organic substances and oxygen in it, which eliminates the emission of harmful substances and the appearance of an unpleasant odor in a bath or sauna, playing an important role for human health.

 Brief Description of the Drawings

 The essence of the claimed device is illustrated by drawings that do not cover and, moreover, do not limit the scope of claims for this decision, but are only illustrative materials of particular cases of the device. The drawings show:

 figure 1 - electric heating furnace for saunas and baths, front view; in FIG. 2 is a section AA in figure 1; in FIG. 3 - section BB in figure 2.

The electric heating furnace for saunas and baths includes a housing 1 with at least one electric heating element located therein 2. Housing 1 is configured to allow heated air to pass through while isolating it from the electric heating element 2. Housing 1 includes at least one upper evaporator 3 and at least one vertical evaporator 4. Upper and vertical evaporators 3,4 made with the possibility of receiving and distributing water intended for vaporization from their surface, with its simultaneous isolation from the electric heating element 2.

 The implementation of the device

The device operates as follows. An electric heating furnace for saunas and baths is connected to the electric network. The electric heating element 2 is heated, transferring its heat to the air passing through the housing 1 of the electric heating furnace. The absence of direct contact of air with an electric heating element allows avoiding the burning of organic substances and oxygen in heated air, which prevents the release of harmful substances and the appearance of an unpleasant odor in a heated room - a bath or a sauna. During the period when the electric heating furnace has completely warmed up, hot water is poured onto the upper evaporator 3 from a ladle or through a special measuring vessel (dispenser) made of talc chlorite, talcocarbonate, talc magnesite or other heat-resistant material with a calibrated hole at the bottom. The degree of water supply to the evaporator is controlled by the size of the hole and the location of the dispenser hole on the surface of the upper evaporator 3. If the sauna heater has several upper evaporators 3, then the water is supplied from the highest evaporator

3, where the heating of water and primary evaporation takes place, then water enters the other upper evaporators installed below, 3. Then water enters the vertical evaporator 4, where the final evaporation takes place. The water distribution system on the surfaces of the evaporators 3,4 is made in such a way that the water is isolated from the electric heating element 2, which increases the reliability and safety of the device, and in addition, excessive evaporation does not occur.

In a preferred embodiment, the device receives and distributes water by making grooves 5 and calibrated channels 6 in the upper and vertical evaporators for receiving and distribution of water over the surfaces of evaporators 3,4 with the exception of water getting on electric heating elements 2. To allow passage of heated air through the housing 1 with its simultaneous isolation from the electric heating element 2, channel-forming 5 elements 7 are arranged in the housing 1, made with the possibility of passing heated air with its simultaneous isolation from the electric heating element 2. The elements of the housing 1 and the channel-forming elements 7 are connected by means of metal studs 8 and / or bolts E fastenings. At least part of these compounds can be equipped with heat-resistant rings 9. To ensure forced air supply to the channel-forming elements 7, they can be equipped with a fan or connected with it.

 As channel-forming elements can be used pipes or plates. They can be made of ceramic and / or fireclay or heat-resistant concrete. In addition, the plates can be made of talc chloride,

15 talc magnesite, or talc carbonate. In one embodiment, the plates made of heat-resistant heat-insulating material are made with longitudinal ribs, which are designed to form channels. They can be oriented in such a way that their longitudinal ribs are directed in the opposite direction from the electric heating element. In this case

20, the plate itself protects the air passing between the longitudinal ribs from the electric heating element. The plates can be oriented in such a way that their longitudinal ribs are directed towards the electric heating element. In this case, the air passing through them is protected by an additionally installed plate protecting the electric heating element 2. It also

25 may be made of talc chloride, talc magnesite, talc carbonate, chamotte or heat-resistant concrete. In another embodiment of the device, the channels can be formed using two plates with longitudinal ribs oriented so that the longitudinal ribs of the first plate are directed towards the longitudinal ribs of the second heat-insulating plate with the formation of channels.

To improve contact with water during its distribution on the surfaces of evaporators 3,4, these surfaces are made rough, for which, as a rule, they are treated with a special metal brush. In a preferred embodiment, as a material having high thermal conductivity, heat capacity and heat resistance, of which body 1 is made, including upper and vertical evaporators 3,4, a natural material is selected, which is a natural 5 environmentally friendly mineral, preferably talchlorite, talc magnesite, talcocarbonate. Recently, a term uniting them - talc stone - has appeared in scientific and technical literature and publications. These minerals can be used individually or together. The listed minerals have similar physical and technical characteristics. They have high heat resistance to temperature extremes from -50 ° С to 1000 ° С, which allows abandoning metal elements in the design of the furnace insert. Their specific gravity is 2,800-2,960 kg / m ³ , which is up to 1.5 times higher than chamotte products, and the thermal conductivity coefficient is 3.37-4.05 W / m * K 5-6 times higher than the chamotte thermal conductivity , What allow

15 to increase the amount of stored heat per unit of time and accelerate the heating of a heated room.

 To ensure safety, the electric heating element 2 can be equipped with a thermal fuse.

 For more comfortable use of the device in terms of regulating the heating temperature 20, the electric heating furnace can be equipped with a temperature controller or connected with it. The temperature controller can be made in the form of an electronic controller or gauge sensor, or in the form of a bimetallic plate. The direct temperature controller is built into the housing 1 according to design decisions. When 25 more complex temperature controllers are used, an opening or other special place for mounting temperature sensors is provided in the body of the electronic power supply. Tumblers or knobs for controlling the temperature of heating the electric heating furnace are installed taking into account the requirements of GOSTs, on a stand or on a remote control panel. The temperature control system may include automatic switching on and off of electric heating elements strictly in time or remotely.

For more comfortable use of the device in terms of humidity control in the room, the device can be additionally equipped water injection system, which can be performed automatically, or semi-automatic, or with manual control.

 The electric heating furnace may be further provided with a switching device configured to provide parallel or serial connection to at least two sources of electricity.

 The housing 1 can be equipped with at least one heat reflector to enhance the heat flux from the electric heating elements towards the vertical evaporator 4. Ceramic or fireclay plates, or plates made of heat-resistant concrete, can be selected as the heat reflector.

 The claimed technical solution has passed practical testing at various power of electric heating elements. The test results showed the advantages of the proposed design, which consists in increasing the reliability and safety of the device during its operation, as well as ease of assembly, ease of use.

Claims

USEFUL MODEL FORMULA 1. An electric heating furnace for saunas and baths, comprising a housing with at least one electric heating element disposed therein, configured to permit the passage of heated air with its simultaneous isolation from the electric heating element, characterized in that the housing includes at least one upper evaporator and at least one vertical evaporator, configured to receive and distribute water intended for vaporization from their surface, at the same time Noah its isolation from the electric heating element. 2. The furnace according to claim 1, characterized in that the upper and vertical evaporators are made with grooves and calibrated channels for receiving and distributing water on the surfaces of the evaporators with the exception of water entering electric heating elements. 3. The furnace according to claim 1, characterized in that its housing is made of a material having high thermal conductivity, heat capacity and heat resistance. 4. The furnace according to claim 1, characterized in that its housing is made of natural material having high thermal conductivity, heat capacity and heat resistance.  5. The furnace according to claim 4, characterized in that the natural material used is talchochlorite, or talc magnesite, or talcocarbonate. 6. The furnace according to any one of claims 1 to 5, characterized in that the upper and vertical evaporators are made of talc chlorite, or talc magnesite, or talcocarbonate. 7. The furnace according to claim 1, characterized in that the channel-forming elements are placed in the housing, made with the possibility of passing the heated air with its simultaneous isolation from the electric heating element. 8. The furnace according to claim 7, characterized in that as the channel-forming elements are used ceramic and / or fireclay pipes, or pipes made of heat-resistant concrete. 9. The furnace according to claim 7, characterized in that as the channel-forming elements, hollow ceramic and / or chamotte plates and / or heat-resistant concrete plates are used. 10. The furnace according to claim 7, characterized in that as the channel-forming elements are used, at least two plates of talc chloride, talc magnesite, or talc carbonate, or heat-resistant concrete. 1 1. The furnace according to claim 7, characterized in that as the channel-forming elements are used plates of heat-resistant heat-insulating material with longitudinal ribs made on them. 12. The furnace according to claim 1, characterized in that the plate of heat-resistant heat-insulating material is oriented in such a way that its longitudinal ribs are directed in the opposite direction from the electric heating element. 13. The furnace according to claim 1, characterized in that the slab of heat-resistant heat-insulating material is oriented in such a way that its longitudinal ribs are directed towards the electric heating element, closed by a stove made of talc chloride, talc magnesite, talc carbonate, chamotte or heat-resistant concrete. 14. The furnace according to claim 11, characterized in that the plate of heat-resistant heat-insulating material is oriented so that its longitudinal ribs are directed towards the longitudinal ribs of another heat-insulating plate with the formation of channels. 15. The furnace according to any one of paragraphs. 7-14, characterized in that the channel-forming elements are equipped with a fan or associated with it. 16. A furnace according to any one of paragraphs. 7-14, characterized in that the housing elements and channel-forming elements are connected by means of metal studs and / or bolt fasteners. 17. The furnace according to claim 1, characterized in that the housing elements are connected by means of metal studs and / or bolt fasteners. 18. The furnace according to claim 1, characterized in that the housing elements are connected by metal studs and / or bolt fasteners, at least some of which are equipped with heat-resistant rings. 19. The furnace according to claim 1, characterized in that the electric heating element is equipped with a thermal fuse.  20. The furnace according to claim 1, characterized in that it is additionally equipped with a temperature controller or associated with it.  21. The furnace according to claim 20, characterized in that the temperature controller is made in the form of an electronic controller.  22. The furnace according to claim 20, characterized in that the temperature controller is made in the form of a gauge sensor.  23. The furnace according to claim 20, characterized in that the temperature controller is made in the form of a bimetallic plate.  24. The furnace according to claim 1, characterized in that it is additionally equipped with a water injection system.  25. The furnace according to claim 1, characterized in that it is further provided with a switching device configured to provide parallel or serial connection to at least two sources of electricity. 26. The furnace according to claim 1, characterized in that the casing is provided with at least one heat reflector for enhancing the heat flux from the electric heating elements towards the vertical evaporator. 27. The furnace according to claim 26, characterized in that ceramic or chamotte slabs or heat-resistant concrete slabs are selected as the heat reflector.  28. The furnace according to claim 1, characterized in that the surface of the housing elements, including the upper and vertical evaporators, is made rough.