DE3925549A1 - Instantaneous throughflow water heater - comprises insulator casing for fluid passages heated by thick-film resistor layers - Google Patents

Abstract

An instantaneous flow water heater consists of a hollow casing, made of insulating material and with a rectangular cross-section which is traversed, e.g. by three parallel meandering passages. The heating is effected by heating resistance tracks imprinted on the insulator material surface by a thick-film technique to suit the pattern of the fluid passages. A ceramic casing (10) which can be produced by extrusion, pref. from cordierite, has three parallel passages (11') for the fluid which are joined in series and with an inlet and outlet (arrows). Three heating elements (7') are applied as thick film resistors by a thick-film technique. ADVANTAGE - Has very high efficiency, yet it can be produced simply and at low cost.

Description

The present invention relates to an electrical Heating device, in particular water heater with a hollow body for receiving and carrying out the heating fluids, with one arranged on the hollow body Heat source for transferring the heat generated to the Fluid, as well as with connections for attaching a or derivation.

An object of the present invention is to: electric heating device, in particular a through to create a heater which has a high thermal However, efficiency is guaranteed in simple and is inexpensive to manufacture.

This object is achieved in that the Hollow body consists of an insulator and as heat source a heating resistance layer is provided, which heated the hollow body and the fluid contained therein.

The insulator expediently consists of a ceramic material.

The advantage of using ceramic material is that ceramic materials usually on the one hand very heat-resistant on the other hand a high one Have shock temperature resistance. Furthermore can ceramic materials in a simple manner undergo a continuous manufacturing process. In addition, the invention has the advantage that the heat formed as a heating resistance layer  also source production technically simply on the Hollow body can be applied, making a very good overall economically manufactured heating device or Instantaneous water heater can be created.

The heating resistor layer can advantageously also be printed on the hollow body. The imprint is preferably done in thick film technology. The imprint ensures the advantage that any heating resistor base layer structures are very easy to print on, which also creates a special heating characteristic (Heating temperature profile, selective heating, surfaces moderate heating etc. can be carried out if necessary.

To make it particularly simple and therefore Ensuring low costs is according to one further expedient embodiment of the invention Extruded hollow body.

The heating resistance layer is expediently in accordance with a further embodiment of the heating according to the invention establishment according to the arrangement and / or off formation of the hollow body in its position and / or Aus education adapted. This allows the Fluidver run within the hollow body, for example by means of a correspondingly arranged heating resistance layer particularly easy to match. By these measures can increase thermal efficiency will.

The fact that - according to another expedient design of the heating device according to the invention - the Heating power of the heating resistor layer via an option switch is adjustable, an additional Possibility of varying the heating outputs guaranteed.  

This allows the same heating resistance layer the setting of a different heating output guarantee. This principle can just as well several separate heating resistor layers, which over separate selector switches can be controlled will. All in all, this allows the setting Availability of one of the heating output characteristics is very strong increase.

Another useful embodiment of the fiction moderate heating device is characterized in that the hollow body from a plurality of each other parallel lines exist. This can the "residence time" of the fluid in the area of the heat source can be increased by making the lines "in series" switches so that the fluid is all parallel to each other flowing lines. Own in this If the individual lines have open ends, so too in this case extrusion is possible.

In the same way or based on the same considerations the hollow body can emerge from at least one exist in a labyrinthine line.

Appropriately are at the end regions of the hollow body each provided closure elements, whereby a simple assembly of the heating device is carried out can be.

The fact that according to a further embodiment of the holding device according to the invention in one and the same Hollow body by varying the end elements Flow length is variable, it is ensured that the actual hollow body is a "standardized" Ausge can possess design, whereby differed by use  Licher closure elements the required flow length are created according to the requirements can.

To ensure a "series connection" of the individual lines of the hollow body, it is expedient to provide channels in the closure elements, the one Ensure flow connection of the individual lines Afford. This allows - without changing the strand pressing base - a simple redirection of the Fluids from one to the other line of the hollow body.

According to the closing elements on the End regions of the hollow body are designed to be pluggable be.

Another useful embodiment of the Invention contemporary heating device is characterized in that at least one back integrated into the end element check valve is provided. This is advantageous Safely ensures that with one pass necessary check valve not separately in the heater Fluid line must be provided.

In the event that the heating device - according to a further appropriate embodiment of the present Invention - at least one in the closure element integrated temperature controller and / or an integrated Fuses, a heating module is created which only the electrical connections as well the water connections must be made. This leads to a considerable relief in the devices assembly, resulting in significant cost savings Has.  

The end elements expediently consist of Plastic, making it easy to manufacture, for example perform in the injection molding process or the like is cash.

To avoid leakage of fluid, a Sealing element for sealing the hollow body and Ab closing element may be provided.

To further simplify assembly, at least a termination element has at least one connection, which can be connected to a fluid-carrying line.

A seal can also be used without a sealing element by constructive measures (preferably a clamp seat between the hollow body and the end element) will.

To hold the hollow body between the two Ab Ensuring closing elements is according to a further embodiment of the present invention - the Hollow body fixed with a bracket.

This holder preferably consists of a spring, which the two closure elements and the one in between arranged hollow body holds together.

Another embodiment of the heater according to the invention facility is characterized in that the ceramic material is cordierite. Owns cordierite on the one hand the advantage of a very high shock temperature on the other hand the possibility of realizing the Extrusion. Cordierite is also special well suited with an electric heating resistor stand layer to be printed.

In the following, only a single embodiment is intended the electr. Heater under Using the drawing figures explained in more detail will. Show it:

Figure 1 is a schematic representation of a system or device for heating a fluid.

Fig. 2 shows a hollow body of the electr. Angle heater from three different angles; and

Fig. 3 shows two closure elements for receiving the hollow body according to the invention, the flow direction of the fluid being shown schematically.

Reference numeral 1 in Fig. 1 denotes a heating device, which is connected via a feed line 4 to a fluid reservoir 2 (for example a water reservoir). To convey the fluid from the reservoir 2 to the holding device 1 , the feed line 4 can have a pump 3 or the like.

Within the heating device 1 , the fluid is heated and supplied to the consumer or the consumer device 6 via the discharge line 5 .

The holding device 1 comprises a heating resistance layer 7 , which is connected to an electrical energy source 8 .

The formation of the hollow body 10 and its coating with a resistance layer 7 is explained in more detail in FIG. 2. In the present case, the hollow body 10 has a cuboid shape and is penetrated by three lines 11 lying next to one another. The lines 11 each open into the side surface of the hollow body 10 . This shape ensures the possibility of producing the hollow body 10 in a simple and inexpensive manner with the help of an extrusion process.

The hollow body 10 expediently consists of an insulator, preferably of a ceramic material. Cordierite, which has a very high temperature shock resistance and can also be printed with a resistance heating layer, is particularly suitable. In particular, sufficient adhesion between the resistance heating layer 7 and a cordierite insulator is ensured.

At the top of the hollow body 10 is a heating resistance layer 7 , which has three zones 7 'to 7 '''. With the help of printing technology, the possibility is created to form heating resistor layers 7 adapted to the lines 11 on the one hand, and on the other hand to vary the heating resistor layer 7 in accordance with the requirements for the heating intensity.

We can be seen from Fig. 2, three different heating resistance layers 7 'to 7 ''' are provided on the top of the hollow body 10 according to the arrangement of the mutually parallel lines ( 11 'to 11 ''').

This technology ensures that the fluid flowing into the lines 7 (see arrow in FIG. 2) reaches a temperature range T ₁ . From this temperature range, the fluid flows further into the channel 11 '', in which a temperature T ₂ <T ₁ prevails. Finally, the fluid enters the line 11 ''', in which a temperature T ₃ <T ₂ prevails. The fluid consequently flows through an increasing temperature profile.

The setting of a temperature profile without temperature Holes or cracks are very quiet working water heater because of a continuous Heating of the fluid can be ensured in this way can ver and noise-causing temperature jumps be avoided.

The corresponding heating resistance layer ( 7 'to 7 ''') can be technically realized in a simple manner by the respective print pattern.

Fig. 3 shows closure elements 14 and 15 which are adapted to the (for clarity not shown), hollow body to be slipped 10th For this purpose, the end elements 14 and 15 each have an axial recess 21 or 22 , which is open to one side and into which the respective end region of the hollow body 10 is inserted. The end elements 14 and 15 are shown enlarged in Fig. 3 for clarity.

In the illustrated in Fig. 3 embodiment 14, the termination element has a terminal 12 which is bestimnt to receive the supply line 14. The second connection 13 of the connection element 14 is intended to receive the derivative 5 .

Channels 16 - 18 are provided for connecting the lines 11 'to 11 ''' provided in the hollow body 10 . Through these channels, the lines 11 'to 11 ''' are connected in series.

The fluid to be heated takes up inside the heater direction a course, which, with the known drawn line is shown. Through this flow leadership can depend on the Ab closing elements the residence time of the fluid within the Hollow body can be varied.

In order to ensure a firm fit of the two end elements 14 and 15 on the hollow body 10 , a spring 20 is provided which engages around the arrangement consisting of end elements 14 , 15 and hollow body 10 and engages, for example, in recesses (not shown) on the end elements.

The end elements 14 and 15 are preferably made of temperature-resistant plastic material, which can be subjected to a shaping process in a simple manner.

Reference symbol list

1 heater
2 reservoir
3 pump
4 feed line
5 derivative
6 consumption device
7 heating resistance layer
8 energy source
9 fluid
10 hollow bodies
11 line
12 connecting element
13 connecting element
14 closing element
15 closing element
16 channel
17 channel
20 spring
21 recess
22 recess

Claims (22)

1. Electrical heating device, in particular by means of a heater with a hollow body for receiving and carrying out the fluid to be heated, with a heat source arranged on the hollow body for transferring the heat generated to the fluid with connections for attaching an inlet or outlet, characterized in that Hollow body ( 10 ) consists of an insulator and a heating resistor layer ( 7 ) is provided as a heat source, which heats the hollow body and thus the fluid ( 9 ) contained therein. 2. Heating device according to claim 1, characterized, that the insulator is made of a ceramic material consists. 3. Heating device according to claim 1 or 2, characterized in that the heating resistance layer ( 7 ) on the hollow body ( 10 ) is printed. 4. Heating device according to claim 3, characterized, that the printing is done in thick film technology. 5. Heating device according to claims 1 to 3, characterized in that the heating resistor layer ( 7 ) is adapted in its position and / or training in accordance with the arrangement or design of the hollow body ( 10 ). 6. Heating device according to one of the preceding claims, characterized in that the heating power of the heating resistor layer ( 7 ) or layers are adjustable via a selector switch. 7. Heating device according to claims 1-6, characterized in that the hollow body ( 10 ) is extrudable. 8. Heating device according to claims 1-6, characterized in that the hollow body ( 10 ) consists of a plurality of mutually parallel lines ( 11 ). 9. Heating device according to claims 1-4 and 6, characterized in that the hollow body ( 11 ) consists of at least one labyrinthine line. 10. Heating device according to claims 1-9, characterized in that each end elements ( 14 , 15 ) are provided at the end regions of the hollow body. 11. Heating device according to claim 10, characterized in that the flow length can be varied in one and the same hollow body ( 10 ) by varying the end elements ( 14 , 15 ). 12. Heating device according to claim 10 or 11, characterized in that in the closure elements ( 14 , 15 ) channels ( 16 , 17 , 18 ) are provided which ensure a flow connection of the individual lines ( 11 ). 13. Heating device according to claims 10-12, characterized in that the end elements ( 14 , 15 ) on the end areas of the hollow body ( 10 ) can be plugged. 14. Heating device according to claims 10-13, characterized in that at least one end element ( 14 ) has a check valve integrated into the end element. 15. Heating device according to claims 10-14, characterized in that at least one end element ( 14 ) has an integrated in the end element temperature controller and / or an integrated fuse. 16. Heating device according to claims 10-15, characterized in that at least one end element ( 14 ) at least ens has a connection ( 12 or 13 ) which can be connected to a fluid-carrying line ( 4 or 5 ). 17. Heating device according to claims 10-16, characterized in that the end elements ( 14 , 15 ) consist of plastic. 18. Heating device according to claims 10-17, characterized in that a sealing element for sealing the hollow body ( 10 ) and the end element ( 14 or 15 ) is provided. 19. Heating device according to claims 9-18, characterized in that there is a clamping seat between the hollow body ( 10 ) and the respective end element ( 14 or 15 ). 20. Heating device according to claims 10-19, characterized in that the hollow body ( 10 ) between the two end elements ( 14 , 15 ) is held ung by means of a holder. 21. Heating device according to claim 20, characterized in that a spring ( 20 ) is provided as a holder, which engages on the two end elements ( 14 , 15 ). 22. Heating device according to claims 1-21, characterized, that the ceramic material is cordierite.