DE1579727C - Electric storage heater with heat emission through natural convection - Google Patents

Description

The invention relates to an electric storage heater with heat emission through natural convection, with a storage core, a thermal insulation layer surrounding the storage core and a Housing jacket as well as with a common lower inlet plenum and a common upper one Air passage ducts connecting the outlet plenum and running inside and outside the storage core.

For such a so-called static storage heater, it has become known from German utility model specification 1 877 187 that both eir. The duct leading to cold air running outside the storage core as well as the ducts running inside the storage core for mixing warm and cold air can be controlled by temperature-dependently controlled valve arrangements. The duct carrying cold air with its valve arrangement represents a so-called "by-pass" system in order to mix cold air into the hot air rising in the ducts of the storage core, depending on the temperature. The hot air ducts assigned to the storage core; Valve assemblies are mutually mechanise "; coupled and restrict the temperature dependent ν these channels rising warm air more or wc niger.

With the static memory described above; device from which the invention is based are already b '. Beginning of the discharge, the air passage channels di hot storage core are controlled, albeit Gegi. In the event of a severe throttling by means of the temp temperature-controlled valve arrangement for: Channels.

Since at the beginning of the unloading process due to d

large temperature difference between the air in the storage ducts and the outside air If static tension is set, the throttling of the storage channels is more or less ineffective because the static pull resulting from the mentioned temperature difference to an increased air velocity leads in the valve area. A sensitive heat emission is therefore at least at the beginning of the discharge process hardly feasible.

The invention is based on the task of discharging a static storage heater of the type defined at the outset using the temperature-dependent air passage channels dominating controlled valve arrangements to make optimal, that is convective heat losses through the very hot air in the air ducts of the storage core at the beginning of the discharge process to a large extent to prevent and to ensure a sensitively controllable heat emission. The invention The main finding is that heat also flows through a thermal insulation layer, i.e. overflows the thickness of the thermal insulation layer sets a temperature gradient. Following this knowledge, there is the The solution to the problem is that at least one further air passage channel connected to the collecting spaces the thermal insulation layer runs through and is also controlled by a temperature-dependent one Valve arrangement is mastered, the valve arrangements initially at the beginning of the unloading process the air passage ducts running in zones of low temperature and as it progresses Discharge the air passage channels running in zones of higher temperature one after the other from the Release colder to warmer temperature zones.

This creates an optimum of a systematically regulated, continuously progressing from the outside to the inside causes convective discharge of the individual zones having different temperatures, this goes hand in hand with compliance with a certain amount to be given to the room to be heated Amount of heat over a long discharge period because the heat from the storage core through canals is used relatively late and not at the beginning of the discharge determines the static pull. The static that gradually diminishes in the course of the discharge Train in channels of one temperature zone is in each case caused by the excess of channels in the next automatically added to higher temperature zone; so that balanced thermal in the outlet plenum Conditions prevail.

The storage heater according to the invention expediently receives three pairs of air passage channels, which run in pairs symmetrically to the center perpendicular of the memory core, one of which is a pair of channels between the thermal insulation layer and the housing wall, another pair of channels runs the thermal insulation layer and the third pair of channels runs through the memory core. The arrangement of pairs in the same temperature zones lying air passage channels allows the valve assemblies in the lower, cold air leading inlet plenum to be relocated and particularly easy to design. In further Embodiment of the invention is therefore proposed that arranged bowl-shaped nested tubs in the inlet collecting space which, due to their air gap from one another, form an inlet-side chamber for each channel pair, which can be opened and closed one after the other with respect to the inlet plenum through telescopically guided valves are. The valves are expediently formed by plates, which by their own weight or close the openings of the tubs lying one above the other under spring pressure when the device charged or when no heat is called up, and of which the lower valve plate to open the chamber associated with the pair of channels of the lowest temperature zone from a thermally controllable chamber Adjusting member can be raised, the

, other valve plates increasingly larger dimensions have and as the heater discharges one after the other from the lower, controlled Valve plate are dragged along.

The thermally influenced adjusting element for the valve arrangement consists, for example, of one of an electric heating element heatable bimetallic construction, the heating power of which is from an in the sensor of a temperature regulator arranged in the outlet collecting chamber can be controlled. This heat sensor serves to limit and regulate the temperature of the exiting hot air to a desired one Worth. The control range of the temperature controller is, for example, between 30 and a maximum of 100 ° C, where the maximum value as a limitation of the highest permissible, tolerable temperature of the exiting Warm air is selected. So you have it in hand, the air outlet temperature to the respective requirements adapt as well as to effect slow or fast discharge for the various needs.

The storage heater is equipped in a known manner with a warm air flap that acts as a handle is used to switch the device on and off. According to the invention, namely, a switching contact can be actuated by the warm air flap which is in the closed position the flap has the heating element, the temperature controller and, if necessary, a room thermostat The supply control circuit is interrupted and closes when the flap is opened. The switching contact is in the »off position« when the flap is closed, so that regardless of the heat demand transmitted by a room thermostat, the Can switch off the heater while blocking the hot air outlet at the same time. For commissioning of the device, the warm air flap is opened and thus the control circuit is closed.

The control circuit is according to a further embodiment the invention when a minimum temperature of the exiting warm air is reached a thermal release with switch-on lock can be switched off. This interrupts the control circuit, if at the end of the convective discharge the temperature of the exiting air is a certain Has reached a minimum that no longer brings any heat gain to the room. This thermal trip should only become ineffective again when the warm air flap is closed and the one with it mechanically coupled switching contact in turn opens the circuit. For this purpose, the switch-on lock is activated by the Closing the hot air flap can be unlocked. This switching combination prevents the valve control valve control following the discharge of the storage heater is still kept in operation unnecessarily if the .Warm-Luftklappe is not closed immediately should be.

In addition, the room thermostat can be advantageous for room temperature control in individual furnace systems and without the risk of an immediate temperature influence in the storage heater itself, namely in the Entrance plenum be arranged.

As far as the course of the air passage channels is concerned, these are expediently than in the upper one Part intended to converge towards the front of the device.

In the drawing, a static storage heater according to the invention with three pairs of air passage channels is shown in vertical section. The electrically heated storage core 1 is surrounded by the thermal insulation layer 2 and the housing as the outer furnace cladding. The air passage channels 4 to 9, which correspond in their horizontal extent to the length of the storage heater, are distributed in pairs over three different temperature zones. The channels 4 and 5 run in the lowest temperature zone between the housing walls 3 and the thermal insulation layer. The channels 6 and 7 are formed by an air gap between the correspondingly arranged thermal insulation panels and thus pass through the thermal insulation layer. The channels 8 and 9 finally pass through the highest temperature zone of the storage core 1 '.

Each channel pair has its own inlet-side chamber 10 in the lower part of the storage heater, 11 or 12, each of which is a spatial and performance-related connection between the two represents functionally related air passage channels. The chamber 10 is the channel pair 4 and 5, the chamber 11 to the pair of channels 6 and 7, and. the chamber 12 is assigned to the pair of channels 8 and 9. These chambers are formed by bowl-shaped tubs nested one inside the other with an air gap, in the bases of which openings perpendicularly one above the other are provided, the size of which is chamber-wise increases from bottom to top and that of matching, telescopically guided valves 13, 14, 15 can be covered.

The valves 13, 14, 15 are designed in their shape and dimensions so that they can be used as self-closing valves Close the openings of the chambers 10,11,12 tightly in the rest state, but at the same time still with Enough guides interlock and can be easily pushed into one another when actuated.

At the beginning of the discharge, the valve 13 first lifts from its seat in the floor of the chamber 10 and gives the outside air the way to the air passage channels 4, 5 free. An automatic valve control A thermally influenced adjusting element 16 causes a continuous stroke. The valve 13 therefore slowly pushes into the valve 14. As soon as the chamber 10 is completely open, the Valve 13 with its entire surface from below. at the valve 14 and takes the same with the stroke, whereby the chamber 11 is opened. The two nested valves 13, 14 now lie from below on the valve 15, with which the stroke of the possibly motor-controlled adjustment member is now also transferred to the valve 15 and the chamber 12 is opened. The closing process is analogous in reverse Order.

In the example, an electrically heatable bimetal construction is used as the temperature-dependently controlled setting element 16 provided that their temperature-dependent lifting force from the lower inlet plenum 17 exerts on the valves in a vertical direction of movement. In the event of a power failure, dit Valve assembly can also be operated by hand.

In the upper part of the storage heater di (air ducts 4 to 9 towards the front of the device ir a common outlet plenum 18, des sen outlet opening 19 of a warm air flap 2: is covered, which is behind a protective grille 21 in the dei Housing cover 22 can be moved. Mechanically coupled with de, hot air flap 20 is an elec tric switch contact (not shown), which ver when the warm air flap 20 is closed in the off position waits. As further Schaltete elements, not shown here, are in the outlet plenum 18 a tempera temperature controller and a thermal release with mechanical switch-on lock. This trigger responds when the warm air flap 20 is open to whom the temperature of the exiting air is set to a be correct minimum has decreased, and hardly just mechanically by closing the warm air flap 20 again unlocked and brought to the ready position. With the help of the temperature controller and one of the The temperature of the exiting air can be regulated and controlled by the heat sensor assigned to this controller be bordered.

The natural, convective heat emission from the storage heater is controlled by means of a room thermostat regulated (not shown) which if necessary in the Gt advises itself in the inlet collecting space 17. can be brought. The cold air is close to the floor over the entire circumference of the device through a slot 23 let in.

The switching, control and regulating devices, not shown and connected in series in the control circuit for the natural, convective discharge of the storage heater are made up of space the mostat, mechanical with the hot air flap 20 gi coupled, electrical switching contact, temperature controller with heat sensor in the outlet plenum 1 thermal release in the outlet plenum i and the electrical heating element for actuation d < Bimetal construction of the adjustment member 15.

The mode of operation of the storage heater η Heat dissipation through natural convection is the following:

The device can not only be charged when the air flap 20 is closed due to the subsequent interruption of the control circuit due to the night flow, but also when the warm air flap is still open, since when a minimum temperature of the exiting air is reached, the control flow circuit is also activated by a thermal trigger Egg lockout can be switched off, whereby c valves 13, 14, 15 also remain closed. To start up the charged device, the warm air flap is either opened (if it is closed; or it is closed and opened again in order to unlock the mechanical switch-on lock of the thermal switch. The control circuit is closed by the room thermostat when the temperature is present, whereby the temperature controller 1 enters ACTION and the thermally influenced adjusting · gan 16, which can also be motor-operated gear sets. By first the lower valve plate <valve 13 is raised the cold air flows from d lower inlet plenum 17 through the chamber into the channel pair 4, 5 of the lowest tempera) zone. The heating of the in this channel pair

Due to the static draft of rising air will not be sufficient at the beginning of the heating process, the preset, to achieve the desired temperature of the exiting warm air. Therefore, the adjuster continues 16 continues its stroke and switches by lifting the middle valve 14 and possibly also at high The upper valve 15 opens at the preset target temperature of the exiting air. Over the entire discharge period seen, however, through continuous control of the valve assemblies 13, 14, 15, a natural one that progresses continuously from the outside to the inside across the individual temperature zones convective discharge of the storage heater takes place. The one located in the outlet plenum 18 ensures that

Lent temperature controller that the discharge with a certain temperature of the exiting air and uniform strength of the static pull is done by making the selection required, each coming into engagement valves and their lift height are determined. Because the static pull in the channel pairs different temperature zones is different and gradually changes over the course of the discharge is reduced, a static train deficit in a pair of channels is each made up by the excess automatically added to the channel pair of the next higher temperature zone, so that in the outlet plenum 18 balanced thermal conditions prevail over the entire discharge process.

For this 1 sheet of drawings ■ -

309 620/28

Claims (10)

Patent claims: 1. Electric storage heater with heat dissipation through natural convection, with a Storage core, a thermal insulation layer surrounding the storage core and a housing jacket as well as with a common lower inlet plenum and a common upper outlet plenum connecting inside and air passage channels extending outside the storage core, both at least a duct running outside the storage core and feeling cold air as well as the inside the storage core running channels for mixing warm and cold air depending on the temperature controlled valve arrangements are mastered, characterized in that that at least one further air passage channel connected to the collecting spaces (17, 18) (6, 7) runs through the thermal insulation layer (2) and also depends on the temperature controlled valve arrangement is mastered, the valve arrangements (13 to 15) at the beginning of the unloading process, first the air passage channels running in zones of low temperature (4, 5) and, as the discharge progresses, those in zones of higher temperature Air passage channels (6, 7; 8, 9) one after the other from the colder to the warmer temperature zones release. . 2. Storage heater according to claim 1, characterized by three pairs of air passage channels, which run in pairs symmetrically to the center perpendicular of the memory core (1), of which a pair of channels (4, 5) runs between the thermal insulation layer (2) and the housing wall (3), another pair of channels (6, 7) the thermal insulation layer and the third pair of channels (8, 9) den Memory core runs through. 3. Storage heater according to claim 2, characterized in that in the inlet plenum (17) bowl-shaped nested tubs are arranged, which by their air gap from each other for each channel pair form an inlet-side chamber (10, 11, 12), which through telescopic guided valves (13, 14, 15) open and successively opposite the inlet plenum are controllable. 4. Storage heater according to claim 3, characterized in that the valves (13, 14, 15) of Plates are formed which are superimposed by their own weight or under spring pressure Seal the openings of the bathtubs when the device is charged or when no heat is drawn and of which the lower valve plate for opening the channel pair is the lowest Chamber (10) assigned to the temperature zone by a thermally controllable adjusting element (16) can be raised, the remaining valve plates having increasingly larger dimensions and with progressive discharge of the heater one after the other from the lower, controlled one Valve plate are dragged along. 5. Storage heater according to claim 4, characterized in that the thermally influenced Adjusting member (16) made of a bimetallic construction which is controlled by an electrical heating element consists, the heating power of which is arranged in the outlet plenum (18) The sensor of a temperature controller can be controlled. 6. Storage heater according to claim 5 with one of the outlet plenum closes off to the outside Warm air flap, characterized in that a switching contact can be actuated by the warm air flap (20), which in the closed position of the Flap the heating element, the temperature controller and, if necessary, a room thermostat The supply control circuit is interrupted and closes when the flap is opened. 7. Storage heater according to claim 6, characterized in that the control circuit when reached a minimum warm air outlet temperature through a thermal release with Switch-on lock can be switched off. 8. Storage heater according to claim 7, characterized in that the switch-on lock by the Closing the warm air flap (20) can be unlocked. 9. Storage heater according to claim 6, characterized in that the room thermostat in the Inlet collecting space (17) is arranged. 10. Storage heater according to claim 1 to 9, characterized in that the air passage channels (4 to 9) converge in the upper part towards the front of the device.