WO1987003079A1

WO1987003079A1 - Self-supporting heating element for electric ovens and electric ovens fitted with such elements

Info

Publication number: WO1987003079A1
Application number: PCT/HU1986/000058
Authority: WO
Inventors: Lajos LUDÁNYI; Jutka HÁRSY; István BIRÓ
Original assignee: Mikron Ipari És Szolgáltató Kisszövetkezet
Priority date: 1985-11-11
Filing date: 1986-11-11
Publication date: 1987-05-21

Abstract

An electric heating element, provided between its turns with spacer blocks composed of a heat resistant and electrically insulating material, oxide ceramics for example. Holding pegs are arranged through bores of the spacer blocks and extend through the spacer blocks arranged in a line, retaining them. By using spacer blocks of various thicknesses it is possible to modify the distance between the turns of the heating element. An electric oven provided with this heating element contains spacer blocks which are fixed inside the ceramic shell of the oven, along its longitudinal axis, and heating elements arranged between the spacer blocks.

Description

SELF-SUPPORTING RADIATOR FOR ELECTRIC OVENS AND ELECTRIC OVEN WITH THIS RADIATOR

The invention relates to a self-supporting radiator for electric ovens, which is made of a resistance wire or profile, or tape or an induction coil, this radiator being designed in a known manner spiral or folded and according to the invention spacers made of heat-resistant and electrical between the turns of the radiator insulating material are arranged.

According to the current state of the art, radiators for electric ovens are manufactured using one of the methods below:

when using a wire or tape with a diameter of up to 2 mm, these are wound onto a ceramic or quartz tube and fastened by applying an appropriate insulating compound,

- For larger capacities, wires or strips with a larger cross-section are required a template with a corresponding increase in turns is wound and fastened with an appropriate insulating compound.

The stoves or their radiators designed using these methods have the following shortcomings:

The use of a ceramic tube and an insulating compound leads to a significantly higher energy consumption than the work space would otherwise require and, as a result of the resulting higher temperature requirements, the ceramic or quartz tubes bend in a short time and during operations below a temperature of 1200 ° C and higher the radiators must be replaced frequently. At higher temperatures, the impurities in the mass used, the softening quartz or ceramic tube corrode the heating coil or the belt, making the service life shorter. A special single-purpose machine is required to produce the heating coil or the folded radiator, and special stencils are also used to apply the binder. These deficiencies are remedied by the radiator designed according to the invention. The lifespan of the radiators is longer and the energy consumption is lower.

According to the invention, self-supporting radiators for electric ovens are created, which are folded from a resistance wire or profile or band or formed spirally, with at least two, preferably three, preferably symmetrically arranged spacers made of a heat-resistant and electrical between the turns or folds of the heating element per turn or fat insulating material, preferably ceramic material, insulating stone, quartz,

Porcelain are attached. A bore is formed in each of the spacers and lies parallel to the longitudinal axis of the radiator. A fastening pin is made through the bores and is made of a heat-resistant material, preferably one with the material of the radiator there is identical material and is arranged continuously between the spacers arranged in a row.

According to a preferred embodiment of the heating element according to the invention, spacers with different thicknesses are arranged along the longitudinal axis of the furnace between the individual turns of the heating element.

The use of such spacers changes the winding rise of the radiator and sections with different heat profiles are formed along the longitudinal or vertical axis of the furnace. Such sections with different heat profiles could only be formed by separate electrical feed lines in the previous solutions. These separate supply lines are superfluous in the solution according to the invention, and the construction is simplified.

Of the above-mentioned radiators provided with corresponding spacers, stoves can also be created according to the invention which are further provided with a ceramic covering with a radiator consisting of a resistance wire or a band or a profile, as well as spacers and fastening pins, with on both opposite sides the spacers are grooves which are adapted to the shape and curvature of the resistance wire, profile or band. The resistance wire, the profile or the band rests in these grooves, and the distance between the mutually opposite grooves corresponds to the increase in the number of turns of the heating element, while the end of the individual spacers which protrudes beyond the outer diameter of the heating coil or protrudes from the plane of the folded heating element rests on the ceramic casing of the furnace.

According to a preferred embodiment of the furnace according to the invention, the increase in turns of the radiator along the longitudinal axis of the furnace and / or in the vertical direction by means of spacers with different thicknesses.

As a result, the heat distribution of the furnace can be dimensioned differently along its longitudinal or vertical axis. The individual radiator sections with different winding increases can also be provided with an electrical supply line.

In a further embodiment of the furnace according to the invention, spacers are arranged at the end of the heating coil or the folded radiator, each of which only one side rests on the heating resistor, the projecting ends of the fastening pins of these spacers being provided with a stop. Since the heating elements are self-supporting, their assembly and replacement is easier and cheaper than with conventional furnace designs.

Further features and advantages of the invention will be explained in more detail with reference to the accompanying drawing. In the drawing are:

1A-1C spacer to the inventive

Radiator, with curved grooves in plan view and with different thickness in side view, Fig. 2A-C spacer as in Fig. 1A-1C but with

V-shaped groove profile, Fig. 3A-C spacer as in Fig. 1A-1C but with non-curved grooves and combined groove profile, Fig. 4- Radiator in side view,

Fig. 5 radiator with meandering shape in plan view, Fig.6A-C radiator with circular shape in I'ups looks. The inventive, designed with resistance or inductive radiator 2 consists of a resistance wire 5 or profile or a band 6 or an inductive winding, whereby spacers 8 made of heat-resistant and electrically insulating material are arranged between the turns. These are preferably made of aluminum oxide or porcelain, but can also be made of insulating stone or quartz. Two, preferably three spacers 8 are preferably arranged symmetrically per turn. Each spacer 8 is provided with a bore 1, these bores being arranged parallel to the longitudinal axis of the radiator 2. Fastening pins 7 are arranged in the bores and consist of a heat-resistant material or, in the case of resistance heating systems, preferably of a material identical to the material of the radiator. The fastening pin 8 is arranged continuously between the spacers 8 located in a row. In the case of induction radiators, the fastening pin consists of an electrically insulating material, for example a ceramic material. On the two opposite sides of the spacers 8 grooves h ₁ , h _{p are} formed, in which the heating wire, the profile or the band rests, and which are the shape and curvature r ₁ , r ₂ , r _{3 of} the resistance wire 5 or Adapt induction winding wire, profile or ribbon 6. The distance h ₁ , h ₂ between the mutually opposite grooves corresponds to the increase in the number of turns of the radiator. The end of the part of the individual spacers protruding beyond the outer diameter of the heating coil, or of the part of the spacers protruding from the plane of the folded radiator, rests on the ceramic covering 9 of the furnace 3.

The fastening pins 7 protrude beyond the radiator, fasten it in the longitudinal direction and make it self-supporting. At the end of the last turn of the heating coil or the folded radiator spacers 10 are also arranged, so only one rest on one side of the radiator with the other side exposed. A stop 4 is formed at the end of the fastening pins projecting beyond these spacers. As already mentioned, the end of the spacers 8 projecting beyond the level of the radiator lies on the ceramic casing 9 of the furnace 3. This ensures a gap between the radiator and the external heat insulation. The dimensions of this intermediate space can be adjusted by means of the spacers formed with a suitably selected height and at the same time the centering of the radiator is also released. In this regard, a row of spacers arranged at an angle of 60 ° has proven to be extremely advantageous. In other cases, for example when using an insulation blanket, it is advantageous to arrange the symmetrically arranged spacers rotated by 30 ° per turn. In this way, the spacers form a row along the radiator, on which the insulation material can be wound with certainty and the desired space can also be secured.

Spacers with different thicknesses v ₁ , v _{2 can also} be used along the longitudinal axis of the radiator. By using the spacers with different thickness, the winding increase of the radiator changes and along the longitudinal or vertical axis of the furnace, sections with different heat profiles are formed. Such sections with different heat profiles were formed in the previous solutions by separate electrical leads. These separate feed lines are not required in the solution according to the invention, which simplifies the construction.

In addition to the use of sections with different increases in wind speed, separate sections can of course also be used electrical supply lines are used, this can further exacerbate the differences between the sections with different heat profiles.

When using inner quartz or ceramic tubes, the spacers fix them and keep them centered. The spacers according to the invention can also be used for heating plates, radiant heaters and ovens with a square profile. In this case, the dimensions determine the distribution and number of spacers.

The material used for the fastening elements is preferably an oxide ceramic of appropriate purity formed by extrusion. However, if only a small number of items are to be produced, it is expedient and more economical to manufacture the molded pieces from insulating stone by means of chip removal and to subject them to a thermal treatment at a temperature of 1100-1200 ° C.

The radiators designed according to the invention have the following advantages:

- Costly radiators on which the heating coils are wound or in which they are arranged are not required.

- The fixing of the heating wires is finally released. - There is no need to apply oven mass.

- The lifespan of the elements increases, since the heating wire is only in contact with the fastening elements made of oxide ceramics with a high degree of purity, from the other construction parts of the furnace (quartz, chamotte) no impurities can diffuse into it.

- The fasteners precisely determine the spiral's rise in turns. By using fittings with different thicknesses, the increase in turns within a heating element can be changed as desired. - Since heating elements are self-supporting, their assembly and replacement is easier and cheaper than with conventional furnace designs.

- As a result of the absence of the ceramic tube and the insulating mass, significant energy savings can be achieved.

Claims

1. Self-supporting radiator for electrical

Furnaces which are folded from a resistance wire (5) or profile (5) or ribbon (6) or formed in a spiral, characterized in that between the turns or folds of the radiator (2) per turn or fold at least two, preferably three, preferably Symmetrically arranged spacers (8) made of a heat-resistant and electrically insulating material, preferably ceramic material, insulating stone, quartz, porcelain, are attached, a bore (1) being formed in each of the spacers (8), which is directed towards the longitudinal axis of the radiator (2 ) parallel is that a fastening pin (7) is also passed through the holes, which consists of a heat-resistant material, preferably a material identical to the material of the radiator, and is arranged continuously between the spacers (8) arranged in a row.

2. Radiator according to claim 1, characterized in that along the longitudinal axis of the furnace between the individual turns of the radiator (2) spacer tubes (8) with different thicknesses (v ₁ , v ₂ ) are arranged.

3. Electric furnace with a radiator according to claim 1, wherein this furnace with one of a resistance wire (5), a band (6) or a profile (5) spacers (8) and fastening pins (7) existing radiator (2) and one Ceramic sheath (9) is provided, characterized in that on both opposite to each other Sides of the spacers (8) grooves (h ₁ , h ₂ ) are formed, which are adapted to the shape and curvature (r ₁ , r ₂ , r ₃ ) of the resistance wire (5), profile (5) or band (6) and in which the resistance wire (5), the profile (5) or the band (6) rests, that the distance (h ₁ , h ₂ ) between the mutually opposite grooves corresponds to the increase in the number of turns of the radiator (2), while that over the Outside diameter of the heating coil (5) protruding end of the individual spacers (8) rests on the ceramic casing (9) of the furnace (3).

4. Electric furnace according to claim 3, characterized ge ke nn zele hn et that along the longitudinal axis of the furnace (or in the vertical direction) the increase in turns of the radiator by means of spacers (8) with different thickness (v ₁ , v ₂ ) is changing .

5. Electric furnace according to claim 4, characterized in that the individual radiator sections with different winding increases are each provided with an electrical feed line

6. Oven according to claims 3, 4, 5, characterized geke nn zeic hne t that at the end of the heating coil (5) or the folded radiator (6) spacers (10) are arranged, each of which only one side on the heating resistor rests, the projecting ends of the fastening pins (7) of these spacers being provided with a stop.