The present invention relates to an armored resistor in which is provided a resistance wire inserted in a tube-shaped metal casing, which is filled with electrically insulating material, e.g. magnesium oxide, and to a manufacturing process thereof.
Armored electrical resistors are generally used in household appliances which are in contact with water, such as washing machines, dishwashers, boilers or the like. Typically, these resistors are formed by a resistance wire coaxially inserted in a tubular metal casing, which is filled with electrically insulating powder, e.g. magnesium oxide, which is then consolidated. The resistance wire is connected with pins which protrude from the ends of the casing and which have the function of connecting to the electrical power supply system.
Closing elements which are sealed to the casing are present at each end of the casing.
Disadvantageously, the sealing is generally performed by means of resins, e.g. epoxy or polyurethane. This implies the need to implement particularly complex polymerization processes by means of specific apparatuses, requiring a high degree of accuracy.
Furthermore, the armored resistors are disadvantageously formed by a relatively high number of parts, of which also several parts forming the casing, which are mutually joined, in general by brazing.
The armored resistors may envisage safety devices, typically a thermal fuse, which has the function of interrupting the electrical current in case of unexpected overheating of the heating element. In particular, the thermal fuse is usually arranged outside the tubular casing and electrically connected to the resistance wire by means of brackets, thus making the entire armored resistor bulkier and of more complex construction.
Disadvantageously, an armored resistor of this type has some drawbacks, in particular due to the length of the armored resistor itself. For example, for some applications it is desirable to have an armored resistor which does not exceed a given length. One of the reasons for reducing the size of the armored resistor is that the space available for housing it, is rather small. Another reason is related to excessive resistance, due to the excessive total length of its components, which implies a slower heat transmission from the heating element to the thermal fuse and a lower operating sensitivity of the latter, due to the longer distance between fuse and heating element, with consequent larger dimensions and longer reaction times of the thermal fuse. Less reliability and a shorter working life thus derive.
Although an armored resistor in which the thermal fuse is housed in a closing element has been suggested, such a solution is not free from drawbacks. A disadvantage is that the casing must be pressed in order to provide a better heat exchange between resistance wire and its casing. Such an operation is performed by making the entire armored resistor pass through a roller mill. This implies that the part in which the thermal fuse is housed is also subjected to the rolling pressure with the consequent risk of damaging the thermal fuse, which is a particularly delicate component. Disadvantages also appear when a thermal fuse is not envisaged; indeed, a roller mill cannot be used for compacting armored resistors shorter than a given length.
It is thus felt the need to make an armored resistor which allows to overcome the aforesaid drawbacks.
It is an object of the present invention to provide a more compact armored resistor, in particular shorter than the prior art.
It is another object of the present invention to provide an armored resistor which consists of a lower number of components and which is easier and more cost-effective to make with respect to the prior art.
It is another object of the present invention to provide an armored resistor provided with at least one thermal fuse arranged near the heating element so as to be particularly reactive and reliable in case of malfunctions.
It is a further object of the invention to provide a process for manufacturing such a type of armored resistor.
The present invention thus achieves at least one of the such objects by making an armored resistor which, according to claim 1, comprises
According to an aspect, in accordance with claim 9, the invention provides a process for manufacturing an armored resistor having the features of claim 1, in which there are provided the steps of:
Advantageously, the thermal fuse may be inserted in the closing element, which may be a washer. In this manner, the thermal fuse is near the heating element, i.e. the resistance wire, so as to be promptly and accurately sensitive to malfunctions of the armored resistor or of a device which comprises it, e.g. when excessive heating of the resistance wire occurs.
Advantageously, the closing element provided with at least one opening for filling the casing with insulating material allows a manufacturing process of the armored resistor which is more efficient and more effective than the prior art.
Advantageously, the length of the armored resistor may be less than that of the prior art, e.g. it may be shorter than 250 mm, in particular 120-160 mm.
Advantageously, the casing may be a single metal material extruded, e.g. made of aluminum or stainless steel.
Advantageously, the section of the central portion of the tubular casing may be smaller than the two end portions. Such a geometry of the central portion may be advantageously obtained by pressing from the outside, e.g. by means of jaws. An advantage of being able to press only the central portion of the tubular casing is that the thermal fuse(s) possibly present in the closing element are not subjected to pressing and thus are not damaged by such an operation. Furthermore, the central portion of the tubular casing may have a non-cylindrical shape, while the end portions may be cylindrical. This makes it possible to fix further O-rings about the end portions.
Preferably, the fluid-tight fixing of the closing elements to the casing is performed mechanically, even more preferably in exclusively mechanical manner.
Preferably, the resistance wire is arranged coaxially with respect to the tubular casing.
The dependent claims describe preferred embodiments of the invention.
Further features and advantages of the present invention will be apparent in the light of the detailed description of a preferred, but not exclusive, embodiment of an armored electrical resistor and to a manufacturing process thereof, illustrated by way of non-limitative example, with the aid of the accompanying drawings, in which:
The same reference numbers in the figures identify the same elements or components.
With particular reference to
The closing elements 5, 6 are provided with a respective through hole and both are crossed by a respective pin 11, 12. Each pin 11, 12 is coaxial and electrically connected to the resistance wire 3, in particular to the two ends 13, 14, respectively.
The holes may be completely obstructed by the pins and possibly by other filler material or not. Each pin 11, 12 extends along the longitudinal axis X both inside and outside the tubular casing 2, protruding beyond the closing element 5, 6 in which it is housed. The pins 11, 12 are adapted to be connected to a source of electricity, not shown.
The first closing element 5 is partially inserted in the tubular casing 2. The closing element 5 is provided with a peripheral groove 18. An O-ring 19, e.g. made of elastomeric material, is housed in the peripheral groove 18. The geometric center of the O-ring 19 lies on the longitudinal axis X. By virtue of the O-ring 19, which is arranged fluid-tightly between the groove 18 and the inner wall of the tubular casing 2, a fluid-tight closure is provided between the first closing element 5 and the tubular casing 2.
The second closing element 6, a top plan view of which is shown in
The through hole 20 of the second closing element 6 is preferably obtained in central position with respect to the circular portion 21, in which the pin 12 extends. The pins 11, 12 are shaped so as to be fixed to the respective closing element 5, 6. Preferably, a portion of the part of each pin 11, 12 which is external to the tubular casing 2, and adjacent to the respective closing element 5, 6, has at least two zones 22, the diameter of which is larger than the through hole 20. Such zones can be obtained, for example, by pressing the pin with pincers or appropriate jaws. Each pin 11, 12 also has a portion 23, inside the tubular casing 2, the diameter of which is larger than the hole 20, so as to abut on the closing element 6 inside the tubular casing 2. The pins 11, 12 are fixed to the respective closing element 5, 6 by virtue of the zones 22 and of the portion 23.
According to first variant of the first embodiment shown in
The inner part 34 has a tapered portion 37 and the through hole of the closing element 5′ has a similar geometric part, so that the inner part 34 abuts on the latter and thus on the first closing element 5′.
According to a second variant of the first embodiment, shown in
According to a third variant, not shown, only the second closing element has a thermal fuse incorporated inside.
According to further variants, with reference to
With particular reference to
In particular, the second embodiment comprises the previously described variants. Of the three variants of this embodiment, corresponding to the variants of the previous embodiments, two are shown in
As described for the previous embodiment, the possibility of having the central portion with the section area smaller than the two end portions is also provided. Such a feature is shown in
According to an aspect, the invention also provides a process for manufacturing an armored resistor.
The process includes the following steps.
Step A: inserting each pin 11, 12 into a respective hole of the first closing element 5 and second closing element 6.
Step B: fixing each pin 11, 12, preferably by welding or brazing, to a respective end 13, 14 of the heating element 3, thus producing an intermediate assembly; the intermediate assembly comprises two closing elements 5, 6, the two pins 11, 12, and the resistance wire 3. When one or more thermal fuses are provided, the intermediate assembly also comprises the thermal fuse or thermal fuses and the respective rheophore or rheophores.
Step C: inserting the first assembly into the tubular casing 2, so that the first closing element 5 and the respective pin 11 enter first, and make the first closing element 5 abut on the end 8. For example, the first closing element 5 may be inserted from the end 8 of the tubular casing 2, and may be made to slide in the tubular casing 2 until the protrusions 15 of the second closing element 6 abut on the end 7;
Step D: fixing the first closing element with the end 8 of the casing in fluid-tight or sealed manner; preferably, fixing is performed by inserting the O-ring or by pressing the end 7′ from the outside; once the first closing element 5, is fixed the second closing element 6 is maintained in position also by virtue of the resistance wire 3; indeed, as previously described, the latter is wound as a helix and is dimensioned so as to be able to exert an elastic return on the second closing element 6;
Step E: filling the tubular casing 2 with electrically insulating material in the form of powder by means of the at least one passage 16.
Step F: consolidating the electrically insulating material so as to make it a compact mass; preferably, the electrically insulating material is magnesium oxide, of the type which also comprises a monomer, e.g. siliconic, so that the consolidation of the magnesium oxide may occur by means of heat. The consolidation of the magnesium oxide contributes to holding the assembly described above in position with the tubular casing 2.
The process is particularly advantageous because the filling operation occurs by means of the at least one passage of the second closing element; the fluid-tight closing of the first closing element with the tubular casing, by means of the O-ring and the pressing, prevents the release of the electrically insulating material in powder form during filling.
After step (f) a step (g) may be envisaged in which the central portion of the casing is pressed from the outside. Advantageously, by pressing the portion only, the possible thermal fuses are not damaged.
Furthermore, a step of plugging of the holes by means of filling material may be envisaged.
Number | Date | Country | Kind |
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102015000040138 | Jul 2015 | IT | national |
Filing Document | Filing Date | Country | Kind |
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PCT/IB2016/054574 | 7/29/2016 | WO | 00 |