EP0813030A1 - Frost controller - Google Patents

Abstract

The monitor has a plastic housing with inlets and outlets for the flow of convection air and contains an electrical heating element. The tubular heating body (6) has two straight sections carrying mains connectors (12) and a spirally wound section with two bends (9,10) in the region of the ends facing away from the connectors and a single bend (11) at a distance from the end facing the connectors. The first two bends are radially displaced from each other, at different distances from the connectors. They and the two straight sections are in parallel planes and the single bend is inclined to these planes.

Description

The invention relates to a frost monitor with a supply and exhaust air openings for a convection air flow receiving housing, in particular made of plastic and with an electrical heating element.

It is known for electrical frost monitors to arrange the electrical heating element in the region of a convection air flow in order to dissipate the amount of heat generated to the room by means of the convection air flow. It has been shown that the heating elements, especially in areas with accumulations of windings, generate temperature peaks that are only sluggish or non-degradable due to the convection air flow and that give rise to partial overheating to destroy or damage the frost monitor, in particular the receptacle housing.

It is an object of the invention to provide measures to prevent undesirable temperature peaks in the housing of frost monitors.

According to the invention, this object is achieved by a tubular heating element with two straight connections having network connections and a spirally wound tubular heating element section with two deflection bends arranged in the area of the end facing away from the network connections and a single deflection bend arranged at a distance from the end facing the network connections, whereby the extend two deflection bends radially offset from each other with different distances to the network connections. The two deflection bends are preferred and the straight sections of the tubular heating element are formed in mutually parallel planes, while the individual deflection bend is directed obliquely to the planes of the two deflection bends. In this way, there is a large-scale distribution of the heating sections in the convection air flow, which enables uniform heat emissions to the convection air flow, which leads to a heating of the convection air and the receiving housing that remains within predetermined limits without the formation of heat accumulations and temperature peaks. The absence of temperature peaks is advantageous when heat-sensitive materials, for example plastics, are used to form the housing. In addition, the absence of temperature peaks easily takes into account the overheating protection regulations for electrical heating devices.

In an embodiment of the frost monitor, it is provided that the straight sections of the tubular heater have thermally inactive zones over first areas adjoining the network connections, and that a thermally active second area formed by sections of the straight sections and the deflection bend is connected to the thermally inactive zones. The thermally inactive zones in the area of the mains connections prevent damage, e.g. Corrosion on these and contribute to the uniform heat dissipation over predetermined areas to the interior of the receiving housing.

To fix the tubular heating element in the receiving housing, it is provided that the tubular heating element with the straight sections, preferably the end regions having the network connections, be passed through lead-through openings of a carrier board and fixed with the straight sections on the carrier board. The fixation can be done arbitrarily, e.g. by screwing. In addition, measures for fixing the carrier board in the receiving housing are provided. For this purpose, the carrier board can be held in the receiving housing, for example by means of clamping means. The carrier board can also be oriented in any manner in the receiving housing, preferably inclined at an angle to the vertical longitudinal orientation of the receiving housing, and can be fixed in the receiving housing. There is also the possibility of accommodating the support plate for the tubular heating element with a vertical longitudinal orientation to the vertical longitudinal orientation of the receiving housing in the latter.

Finally, as a contribution to preventing heat build-up in the receptacle housing, it is also provided that the carrier board has a number of openings for warm air dissipation directly next to the through-openings for the straight sections of the tubular heater and in areas at a distance from the through-openings. The openings can be of any size, number and spacing from one another.

Fig. 1

einen Frostwächter im Schnitt,

Fig. 2

einen Rohrheizkörper in Seitenansicht, vergrößert,

Fig. 3

einen Rohrheizkörper in Draufsicht, vergrößert und

Fig. 4

eine als Befestigungsglied für den Rohrheizkörper dienende Trägerplatine in Seitenansicht.

The embodiment shown in the figures shows how the invention can be carried out. Here mean:

Fig. 1

a frost guard on average,

Fig. 2

a tubular heater in side view, enlarged,

Fig. 3

a tubular heater in top view, enlarged and

Fig. 4

a serving as a fastener for the tubular heater support board in side view.

In the figures, 1 denotes the housing of a frost monitor, which has supply air openings 2 in the base area and 3 exhaust air openings 4 in the front side for a convection air flow passing through the receiving housing 1. In the receiving housing 1, a board 5 (Fig. 4) is fixed, which serves as a support for a tubular heater 6 (Fig. 2,3). The tubular heater 6 has two straight sections 6 ', 6' 'which, for fixing the tubular heater 6 on the carrier board 5, pass through through openings 7 of the carrier board 5 and on the carrier board 5, e.g. are held by screw 8 or clamp body.

The straight sections 6 'and 6' 'of the tubular heater 6 are followed by two deflection bends 9 and 10 at one end and a single deflection bend 11 in the area of the other end. The deflection bends 9, 10, 11, together with sections of the straight sections 6 ', 6' ', form a spirally wound tubular heater section. The deflection bend 9, 10 and the straight pipe sections 6 ′, 6 ″ essentially extend, as shown in FIG. 4, in parallel planes to one another, while the deflection bend 11 is directed obliquely to the parallel planes.

The straight pipe sections 6 ', 6''have a first thermally inactive zone 16 at the ends facing the network connections 12, which on the one hand ensures damage-free fastening of the tubular heating element 6 to the support plate 5 and which also supports the uniformity of heat emissions to the convection air flow. For further distribution of heat-emitting areas on the tubular heating element 6, the two deflection bends 9, 10 are offset from one another in the longitudinal direction of the tubular heating element 6 and are formed at different distances from the mains connections 12. The transferred training the deflection bend 9, 10 leads to heat emission zones extending largely over a wide area of the tubular heating element 6, which preclude the formation of temperature peaks. The avoidance of temperature peaks is particularly noticeable when the spiraling sections 6 ′, 6 ″ and 9, 10 of the tubular heating element 6 come to lie one above the other or partially one above the other, as a result of the erection of the support plate 5 into the vertical position staggered training Warming zones are located in adjacent areas. In the case of deflection bends 9, 10 formed at equal distances from the network connections 12 or sections 6 ′, 6 ″ located one above the other, there would be narrowly defined zones with intensive heat emissions in their areas, which form temperature peaks. As a result, the convection air flow would be heated unevenly and partial overheating of the receiving housing 1 would result. Partial overheating of the receptacle housing 1 must be avoided in particular if the receptacle housing is formed by plastics.

For additional heat dissipation, a number of openings 14 for warm air dissipation are provided directly next to the lead-through openings 7 of the circuit board 5. In addition, 7 further areas 15 are provided in the support plate 5 with openings 14 for warm air discharge in addition to the through openings. It goes without saying that the thermally inactive areas of the straight sections 6 ', 6' 'can optionally be formed with any length.

Claims (8)

Frost monitor with a supply and exhaust air openings for a convection air flow receiving housing, in particular made of plastic and with an electrical heating element, characterized by a tubular heater (6) with two network connections (12) straight sections (6 ', 6' ') and a spiral wound Tubular heating element section with two deflection bends (9, 10) arranged in the region of the end facing away from the network connections (12) and a single deflection bend (11) arranged at a distance from the end facing the network connections (12), the two deflection bends (9, 10 ) extend radially offset from each other with different distances from the mains connections (12). Frost monitor according to claim 1, characterized in that the two deflection bends (9, 10) and the two straight sections (6 ', 6' ') of the tubular heater (6) are in mutually parallel planes and the individual deflection bend (11) obliquely to the Levels are formed extending. Frost monitor according to claim 1, characterized in that the two straight sections (6 ', 6'') of the tubular heater (6) have thermally inactive zones (16) above the first areas adjoining the network connections (12) and that the thermally inactive zones inactive zones (16) is connected to a thermally active second region (17) formed by straight sections of the sections (6 ', 6'') and the deflection bend (9, 10, 11). Frost monitor according to claim 1, characterized in that the tubular heater (6) with the ends of the straight sections (6 ', 6' ') passes through openings (7) in a carrier plate (5) and with the straight sections (6', 6 '' ) on the carrier board (5) can be fixed. Frost monitor according to Claim 4, characterized in that the support plate (5) for the tubular heating element can be fixed in the receiving housing by means of clamping means. Frost monitor according to Claims 4 and 5, characterized in that the support plate (5) for the tubular heating element is accommodated in the receiving housing (1) at an angle to the vertical longitudinal orientation of the receiving housing (1). Frost monitor according to Claims 4 and 5, characterized in that the support plate (5) for the tubular heating element extends with a vertical longitudinal orientation to the vertical longitudinal orientation of the receiving housing (1). Frost monitor according to claims 4, 6 and 7, characterized in that the carrier plate (5) is located directly next to the through openings (7) for the straight sections (6 ', 6' ') of the tubular heater (6) and in areas (15) at a distance apart the lead-through openings (7) each have a number of openings (14) for warm air discharge.

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