DE3626116A1 - THERMOSTATIC CONTROL UNIT FOR HEATERS OR HEATING UNITS - Google Patents

Abstract

The regulating system comprises a socket-type housing (1), a screw-type rotary regulator (2) and a cap (3) which covers this device. It also includes a heating regulation system provided with a collector ring (5). The socket-type housing clips onto the body of a heating unit valve. A threaded portion (13) of the regulator (2) engages at its upper end with a coarse female thread (12) and surrounds a cylindrical transmission element provided with a pressure spring. This element provides the connection between the valve to be closed axially and the temperature sensor (14). Depending on the preset temperature, the rotary regulator is screwed into the female thread (12) over a variable distance. In order to set the ambient temperature, three resistor-heating elements (18) are fixed to the periphery of the regulator and directly heat the temperature sensor. The latter then controls the closure of the valve. The current is supplied by a low-voltage cable (20) to the collector ring (5) which has concentric sliding contact tracks (25, 26) and connection tracks (27, 28). On the sliding contact tracks (25, 26) are located telescopic bars (41, 42) to collect the current. In this way, the danger of a short circuit due to damage of the cable insulation at the rotary connections is avoided.

Description

The invention relates to a thermostatic control device for heating gene or heating units, with a temperature button, the at least one depending on the sensed temperature variable dimension points and between a fixed base housing and a rotatable one Steller is held with at least one on the rotatable adjuster brought electrical control heating element to heat the temperature button beyond its ambient temperature, and with one over the swivel connection to the adjuster for the control heater element.

A thermostatic control device of this type is known from German Offenlegungsschrift 34 41 695. One or more serve Control or heating elements to adjust the temperature to be adjusted as required to be able to reduce or stop the regulation entirely by the fact that Ta controlling the regulation or influencing it by its thermal expansion always at a key temperature above room temperature is held. The heating elements required for this are so weak that you Electricity consumption can also be neglected over the year. The Control can be made dependent on any process, in particular by adjusting an opening lock such as a window or a door that can be operated directly or via a push button switch Switching elements switch on the heating element or the heating elements solves.  

However, since most are attached to a radiator valve or the like Control devices of the temperature button controlling the valve has rotatable adjuster, it is necessary to also turn on the heating elements attach this adjuster and the slewing ring by a suitable Bridge power supply.

According to the prior publication, an electrical low serves this purpose voltage cable, which from a supply unit through a non-rotatable Holding base housing with loosely placed spiral shape over the rotary ver binding to the control heater attached to the rotatable adjuster element or a heating unit formed from several heating elements to be led.

The power path connections can in principle be permanently set up there or formed by solder joints, but the loose spiral cable scrubs itself in the usual setting processes for the desired room temperature slightly at the edges of the non-rotatable device part, what easily leads to short circuits and also tearing off the connections Can have consequences.

The invention is based on the control device and pursues the task of the operational safety of such control devices to improve that the sources of danger for short circuits and tearing connections in the area of the slewing ring are avoided.

To solve this problem, according to the invention, are centered on the rotary ver binding a slip ring arrangement with at least two electrically separated, slip ring surfaces fixed on the base housing and on the rotating adjustable adjuster two resiliently against the slip ring surfaces Sliding contacts provided.

In this way, flexible live cables are in principle only Valve housing required, i.e. the risk of damage from Grinding operations not suspended, and a verver on the rotatable part easy connection of the sliding contacts for the heating element or elements easily be ensured. You can usually on the base housing  Remove the screwed adjuster with the sliding contacts as required, without having to manipulate anything. The base housing can Valve housing firmly attached to the heating valve, but also any how and where in the room arranged support part, from which one Most heating systems in all rooms of a house or even control or influence a complex of houses.

The slip ring assembly can be a ring attached to the receptacle housing have washer made of insulating plastic, two on the tactile side live ring or segment surfaces made of electrically well conductive, has wear and corrosion resistant material. This grinding ring contact surfaces can basically be exposed in the axial direction, can be shielded expediently in the radial direction. You can can be almost arbitrarily thin and can be sprayed onto the carrier disc hen, vapor deposition or the like. A contact material.

The design of the sliding contacts is currently preferred as resilient common telescopic rods, between which one or more control heating elements if necessary are switched on directly. Such telescopic rods can each by two electrically conductive and conveniently ge at their outer ends closed or at least narrowed pipes are formed, the one between enclose its two outer ends acting helical compression spring. One of the The two tubes are then used for mounting in the rotatable adjuster and that other is against the grinding by the enclosed helical compression spring ring track pressed. In this way, you can also use a special ders coarse thread between the base housing and adjuster which ver achieve greater spring adjustment travel. Because of the great leadership lengths remain, the contact system between the two pipes is always guaranteed and also reduced the mechanical stress.

The contacting surfaces of both telescopic parts are expediently included a layer of electrically conductive and resistant to corrosion capable material coated. The is recommended for the coating materials Use of different precious metals, especially gold and silver. At the small surfaces to be considered and the thin coating  layers, the specific costs of these materials are not particularly high Meaning too. But it is guaranteed that the ruling low voltage = 6 V even under adverse environmental influences security is maintained.

Further features and advantages of the invention are in the subclaims noted and result from the following explanation of the invention based on the drawing. It shows

Fig. 1 in spatially exploded view of a device intended for un indirect connection to a radiator valve control,

Fig. 2 is a partial section through this control device seen in the circumferential direction along the line II-II in Fig. 1 and

Fig. 3 seen a view of the rotary adjuster after removing the cap in the direction of arrow III in Fig. 1.

The control device shown in the drawing is intended for direct attachment to a radiator valve and is divided into a base housing ( 1 ) with a rotary adjuster ( 2 ) that can be screwed into it and a cap ( 3 ) covering the adjuster, a control heating device ( 4 ) on Rotary adjuster ( 2 ) and a slip ring arrangement ( 5 ) between the parts ( 1 ) and ( 2 ).

The base housing ( 1 ) can be mounted with a ring nut rotatably mounted on it ( 11 ) on the valve housing of a radiator valve. At its upper end it has a coarse nut thread ( 12 ) with a pitch of approx. 4 mm, into which a threaded connector ( 13 ) provided at the bottom of the adjuster ( 2 ), usually formed by several segments, engages. This threaded connector encloses an approximately cylindrical transmission body, not shown here, which is provided with the compression spring and which provides the connection of the radiator valve to be closed by axial pressure with the temperature button ( 14 ) indicated only schematically in FIG. 1. This temperature sensor is also essentially designed as a cylindrical body, the volume of which increases at an elevated temperature and decreases as the temperature decreases. To control the radiator valve, only the axial length of the temperature button is used. If the sensed temperature rises, the valve is throttled more and more and ultimately closed. If the sensed temperature drops, the valve is opened again.

In order to be able to set a reference temperature, the distance between the temperature button ( 14 ) supported in the axial direction in the rotary adjuster ( 2 ) and the base housing ( 1 ) is changed by screwing the adjuster more or less into the nut thread ( 12 ). Corresponding temperature levels are usually shown on the cap ( 3 ). Your Stel development can, however, by changing this cap on the teeth ( 16 ) on the lower flange ( 17 ) of the rotary adjuster ( 2 ) change.

To be able to change the temperature of the heated space without changing the position of the rotary adjuster (2), are the adjuster on the peripheral surface of the rotary (2) comprises three approximately cylindrical resistance heating elements so firmly clamped by a ring belt (19) (18) that the from these heating elements, he generated heat is transferred directly to the temperature button ( 14 ). This button can therefore be quickly heated to a temperature of around 40 degrees with very little power in the order of less than 5 watts and then closes the connected radiator valve completely. But it can also be warmed only slightly by lower voltage, so that only the control temperature is increased by a few degrees compared to the room temperature in the order of magnitude. This can be useful if you want to lower it to night temperature or if you want to provide frost protection. A power source such as a battery on the temperature sensor itself is of little use, because then manual adjustment would be necessary in the area of this temperature sensor and, moreover, a battery hardly brings the necessary voltage stability. However, in order to be able to control the heating device ( 4 ) remotely, low voltage must be supplied from the outside, and for this purpose a cable ( 20 ) is inserted through a recess ( 21 ) into the base housing and up to the slip ring arrangement ( 5 ).

This slip ring arrangement, as can best be seen from Fig. 2, on the upper edge of the inner part ( 23 ) attached annular plastic disc ( 24 ), the top two concentric sliding contact tracks ( 25, 26 ), and below comparable large opposite connecting tracks ( 27, 28 ). The ends of the electrical conductors ( 29, 30 ) of the cable ( 20 ) are soldered to the latter.

In the outer region of the connecting track ( 27 ), an angular groove ( 37 ) is formed in the plastic washer ( 24 ), with which this washer is glued to the upper end of the inner wall ( 38 ) of the base housing ( 1 ) without the screwing-in process of the threaded connector ( 13 ) into the nut thread ( 39 ) formed on the inner wall ( 38 ).

The sliding contact tracks ( 25, 26 ) at the top, like the connecting tracks ( 27, 28 ) at the bottom , are formed by annular layers which are sprayed on or vapor-deposited. The inner ring layers, like the outer ring layers, are conductively connected by means of rivets ( 31, 32 ) passed through the plastic disk ( 24 ).

In addition, the inner ring layers ( 25, 27 ) each have a radial nose projection ( 33 ) which projects laterally stripped in an interruption ( 34 ) of the outer ring layers ( 26, 28 ). In this way, the contact connection for the inner ring layers can be placed on the outside to facilitate soldering. On the peripheral surface, if necessary, also on the inner surface of the plastic disk ( 24 ), however, iso-insulating plastic layers ( 35, 36 ) are expediently attached in order to prevent inadvertent dissipation of the voltage to the outside.

Current collectors designed as telescopic rods ( 41, 42 ) with an outer tube ( 43 ), an inner tube ( 44 ) and one of the two tubes around a helical compression spring ( 45 ) are in contact with the slip ring surfaces formed by the annular layers ( 25 ) and ( 26 ). The outer tubes ( 43 ) are firmly seated in bores ( 46 ) of the flange ( 17 ) so that the rounded end ( 47 ) of the respective inner tube ( 44 ) forms the actual sliding contact. The contact surfaces, practically all surface parts of the outer tubes ( 43 ) are coated with a thin layer of gold, that of the inner tubes ( 44 ) with a thin layer of silver.

In addition, the outer telescopic rod ( 42 ) is assigned to the nose projection ( 33 ) so that it receives some distance from this before jump in its end position, as shown in Fig. 1. The entire swivel angle of an adjustment range is chosen so much less than 360 degrees that the nose projection ( 33 ) is not reached at the other end of the adjustment path.

The upper ends of the outer tubes ( 43 ) are narrowed so that the helical compression spring ( 45 ) can be supported there. Under these ends one of the two ends ( 51, 52 ) of a ring line ( 50 ) is connected, in which all three heating elements ( 18 ) are soldered in series.

Thus, all of the heating elements ( 18 ) forming a control heating device ( 4 ) are switched on at the same time as soon as a voltage is applied to the cable ( 20 ), which can be done by a door switch, window switch, timer or the like. The current flow is secured with great reliability, especially since the risk of corrosion is largely eliminated, as is the risk of contamination and short-circuiting due to damage to the cable sheath.

Deviating from the embodiment shown, it may be advisable to equip the control heating device ( 4 ) with a band-shaped or belt-shaped heating element, which can also be provided with a heat-insulating layer on its exposed outside, possibly in conjunction with a heat reflection layer. In this way, the low electrical power to be applied is reduced even further.

Claims (11)

1. Thermostatic control device for heaters or heating units, with a temperature button ( 14 ) which has at least one dimension that is variable as a function of the sensed temperature and is held between a device-fixed base housing ( 1 ) and a rotatable adjuster ( 2 ), with at least one attached to the rotatable adjusting part's electrical control heating element ( 18 ) for heating the temperature button ( 14 ) above its ambient temperature and with a current connection for the control heating element ( 18 ) via the rotary connection to the adjuster ( 2 ), characterized in that centric for rotating connection a slip ring arrangement ( 5 ) with at least two electrically separate, on the valve body fixed slip ring surfaces ( 25, 26 ) and on the rotatable adjuster ( 2 ) resiliently provided on the slip ring surfaces ( 25, 26 ) abutting sliding contacts ( 41, 42 ) is. 2. Control device according to claim 1, characterized in that the slip ring arrangement ( 5 ) has a carrier disc ( 24 ) attached to the receiving housing made of insulating plastic, which conduct two voltage-carrying ring or segment surfaces ( 25, 26 ) from electrically well on the tactile side the wear and corrosion resistant material. 3. Control device according to claim 2, characterized in that the slip ring surfaces ( 25, 26 ) on the carrier disc ( 24 ) by spraying, vapor deposition or the like layers of contact material are formed GE. 4. Control device according to claim 2 or 3, characterized in that on a contact side opposite the contact side to the Schleifringflä Chen ( 25, 26 ) arranged and optionally formed connecting annular layer body ( 27, 28 ) made of electrical connection material and each with the assigned slip ring sheets ( 25, 26 ) are electrically conductively connected. 5. Control device according to claim 4, characterized in that the outer annular layer body ( 26, 28 ) are electrically connected by means of a rivet-like connection ( 31, 32 ) passed through the carrier disk. 6. Control device according to claim 4, characterized in that the inner annular layer body ( 25, 27 ) have identical radial projections ( 33 ) which in an interruption ( 34 ) of the outer annular layer body ( 26, 28 ) to the outer edge of the carrier disc ( 24 ) protrude and are connected there. 7. Control device according to claim 6, characterized in that the setting angle of rotation of the rotatable adjuster ( 2 ) is made smaller than the segment angle of the segment-shaped slip ring track ( 26 ). 8. Control device according to one of claims 1 to 7, characterized in that the sliding contacts are formed by resilient telescopic rods ( 41, 42 ), between which one or more control heating elements ( 18 ) are switched on. 9. Control device according to claim 8, characterized by the design of the telescopic rods ( 41, 42 ) as two electrically conductive and expediently as closed at their outer ends or at least stepped tubes ( 43, 44 ), which acts between their two outer ends helical compression spring ( 45 ) enclose. 10. Control device according to claim 8 or 9, characterized in that the contacting surfaces of both telescopic parts ( 43, 44 ) are coated with a layer of electrically conductive and corrosion-resistant material. 11. Control device according to claim 10, characterized in that the tensile materials on two mutually adjustable telescopic parts ( 43, 44 ) are formed by different noble metals, in particular gold and silver.