NL2027269B1 - Flow heater for heating a liquid medium - Google Patents

Abstract

The invention relates to a flow-through heater for heating a liquid medium, comprising: - a cylindrical housing, which nested, adjacent and in decreasing outer circumference successively comprises a first flow-through chamber, a heating chamber, a second flow-through chamber and a core chamber, which chambers are preferably arranged concentrically and wherein adjacent chambers have a shared chamber wall, wherein the first and the second flow-through chambers comprise a connecting side adjacent a first side of the cylindrical housing; — at least one heating element, preferably three heating elements, arranged in the heating chamber; - a connecting manifold arranged on a second side located in axial direction opposite the first end of the cylindrical housing, which connecting manifold hydraulically connects the sides located in axial direction opposite the connection sides of the flow chambers; - a first and a second connection opening for coupling to a supply line and a discharge line; - a head manifold, which comprises the first connection opening and the second connection opening and which head manifold hydraulically connects the first and second connection opening to the connection side of the first and the second flow-through chamber, respectively.

Description

Flow-through heater for heating a liquid medium The invention relates to a flow-through heater for heating a liquid medium.

Boilers and flow heaters are known for heating up tap water, for example as post-heating of another heating source, with which it is not efficient to reach a suitable temperature for tap water.

Existing boilers and instantaneous water heaters have the disadvantage that they have a long heating time, which means that a lot of tap water is wasted and comfort for the end user leaves something to be desired. As a result, the efficiency is often relatively low.

It is now an object of the invention to provide a flow heater for heating a liquid medium with which one or more of the above drawbacks can be reduced or even prevented.

This object is achieved according to the invention with a flow-through heater for heating a liquid medium, comprising: - a cylindrical housing, which nested, adjacent and in decreasing outer periphery comprises successively a first flow-through chamber, a heating chamber, a second flow-through chamber and a core chamber, which chambers are preferably arranged concentrically and wherein adjacent chambers have a shared chamber wall, wherein the first and the second flow-through chambers comprise a connection side adjacent to a first side of the cylindrical housing; — at least one heating element, preferably three heating elements, arranged in the heating chamber;

- a connecting manifold arranged on a second side located in axial direction opposite the first end of the cylindrical housing, which connecting manifold hydraulically connects the sides located in axial direction opposite the connection sides of the flow chambers; - a first and a second connection opening for coupling to a supply line and a discharge line; - a head manifold, which comprises the first connection opening and the second connection opening and which head manifold hydraulically connects the first and second connection opening to the connection side of the first and the second flow-through chamber, respectively.

With such a flow heater, the flowing liquid medium, such as tap water, is heated very efficiently.

When the flow heater is mounted with the head manifold at the top and the respective connection openings are coupled to a supply and discharge conduit, respectively, the liquid medium first flows from the supply conduit through the first connection opening via the head manifold to the upper connection side of the first flow-through chamber.

The inner wall of the first flow-through chamber is the outer wall of the adjacent heating chamber.

A very high temperature is reached in the heating chamber by the at least one heating element.

Because the chambers are adjacent, there is a heat-exchanging contact between the heating chamber and the first flow-through chamber.

This causes the liquid medium to heat up as it flows from the connection side to the second end of the first flow-through chamber.

In the connecting manifold, the first flow-through chamber is connected to the second flow-through chamber.

The liquid medium flows through the connecting manifold to the second flow chamber.

The outer wall of the second flow-through chamber is the inner wall of the adjacent heating chamber, so that here too a heat-exchanging contact is created between the heating chamber and the second flow-through chamber. On the connection side of the second flow chamber, the liquid medium flows through the head manifold via the second connection opening to the discharge line.

The discharge and supply lines can also be reversed, whereby a reverse flow direction is obtained in which the liquid medium first flows through the second flow chamber and then the first flow chamber.

Because the flow-through chambers are nested, together with the connecting manifold, viewed in axial section, they form two U-shaped flow-through chambers which are symmetrical with respect to the axis of the cylindrical housing. The heating chamber is then located between the legs of the U.

The number of heating elements arranged in the heating chamber is adjusted to obtain an even heat distribution. For example, with straight elements running from the head manifold to the connecting manifold, a good result can be achieved with three heating elements evenly distributed in the heating chamber.

In an embodiment of a flow-through heater according to the invention, at least one core heating element is arranged in the core chamber.

By arranging a heating element in the core chamber, an additional heat-exchanging effect can be achieved between the core chamber and the second flow-through chamber.

Another embodiment of a flow-through heater according to the invention is a flow-through heater wherein the head manifold is provided with at least one holder for a heating element.

By mounting a heating element in a holder in the head manifold, the position in the heating chamber and/or core chamber can be properly determined and the greatest possible effective length of the heating element is used.

In another embodiment of a flow-through heater according to the invention, at least a rough vacuum prevails in the heating chamber.

By applying a low pressure in the heating chamber, such as a rough or even moderate vacuum, no large overpressure is created when the heating chamber is heated. A rough vacuum is considered to be a negative pressure of up to about 1x10° Pa, with a moderate vacuum there is a pressure in the range 1x10° — 1x10% Pa. To maintain the negative pressure, the heating chamber must be hermetically sealed.

Another embodiment of a flow-through heater according to the invention is a flow-through heater in which the heating chamber is filled with an inert gas.

To protect the at least one heating element, the heating chamber can be filled with an inert gas. Due to the protected atmosphere, the life of the heating element can be increased. To maintain the protective atmosphere, the heating chamber must be hermetically sealed.

In yet another embodiment of the flow-through chamber according to the invention, at least one rough vaculm prevails in the core chamber.

The advantages of applying a low pressure to the core chamber are the same as the heating chamber. To maintain the negative pressure, the core chamber must also be hermetically sealed.

Also according to the invention is an embodiment of a flow-through heater in which the core chamber is filled with an inert gas.

This provides the same advantage as filling the heating chamber with an inert gas.

Also an embodiment of a flow-through heater according to the invention is a flow-through heater in which the core chamber is open near the second side.

In an economical embodiment of a flow heater, the core chamber is open on the side of the connecting manifold. The core chamber can for instance be filled with insulating material.

In a preferred embodiment of a flow-through heater according to the invention, the cylindrical housing has a height measured in the axial direction in the range 30-40cm, preferably 38cm.

With a height in the range 30-40cm, preferably with a height of 38cm, the instantaneous flow heater is suitable for mounting in a kitchen cabinet, for example, while it has also been shown that with this dimensioning and an average tap water flow rate of a household, the minimum required tap water temperature can be reached. without requiring an unusually high connection value.

In another embodiment of a flow-through heater according to the invention, the first flow-through chamber has an outer diameter in the range 18-22cm, preferably 20cm.

An outer diameter of the first flow-through chamber in the range of 18-22cm, preferably 20cm, provides sufficient interior space for the nested chambers.

A preferred embodiment of a flow-through heater according to the invention is an embodiment in which the outer diameter of the heating chamber is 2 cm smaller than the outer diameter of the first flow-through chamber.

Also a preferred embodiment of a flow-through heater according to the invention is an embodiment in which the inner diameter of the second flow-through chamber is 2 cm smaller than the inner diameter of the heating chamber.

The nominal distance between the outer and inner walls of the first and the second flow chamber, respectively, is 1 cm in these embodiments. It has been found that good results can be obtained with this intermediate distance of the walls of one or both flow-through chambers.

Since the adjacent chambers have the chamber walls in common, when the inner diameter of the second flow-through chamber is 2 cm smaller than the inner diameter of the heating chamber, the outer diameter of the core chamber is also 2 cm smaller than the outer diameter of the second flow-through chamber.

In another variant of an embodiment of a flow-through heater according to the invention, the volume of the first flow-through chamber is equal to the volume of the second flow-through chamber.

By making the volume of the two chambers equal, the flow rate of the liquid medium is the same in both flow chambers.

These and other features of the invention will be further elucidated with reference to the accompanying drawings.

Figure 1 shows an axial cross-section of an embodiment of a flow heater according to the invention.

Figure 2 shows a schematic radial cross-section of the chambers of an embodiment of a flow heater according to the invention.

Figure 1 shows an axial cross-section of a flow heater 1 according to the invention. The cylindrical

: housing 2 forms the outer wall of the first flow chamber 3. The header manifold 4 is formed by an upper 5, middle 6 and lower plate 7. Recesses 8 in the lower plate 7 and corresponding recesses 9 in the middle plate 6 connect the first flow chamber 3 hydraulically to the first connection opening 10. The head manifold 4 is connected to the cylindrical housing 2 on the connecting side of the first flow chamber 3. The connecting manifold 11 connects the first flow chamber 3 to the second flow chamber 12. In the two flow chambers 3 and 4 formed by The heating chamber 13 is U-shaped. The core chamber 14 is enclosed by the inner walls 15 of the second flow-through chamber 12.

On the connection side, the second flow chamber 12 is hydraulically connected to a passage 16 arranged in the head manifold 4, which passage is hydraulically connected to a second connection opening, not shown. Two heating elements 17 are arranged in the heating chamber 13.

Figure 2 shows a schematic radial cross-section of the chambers of a flow heater 21 according to the invention. No heating elements are shown in the schematic. The cylindrical housing 22 forms the outer wall of the first flow-through chamber 23. The inner wall 24 of the first flow-through chamber 23 is also the outer wall of the heating chamber 25 in which heating elements can be arranged. The inner wall 26 of the heating chamber 25 is also the outer wall of the second flow chamber 27. The inner wall 28 of the second flow chamber 27 is also the outer wall of the core chamber 29.

The diameter a of the cylindrical housing 22 is 20 cm in this embodiment. The diameter b of the outer wall 24 of the heating chamber 25 is 2 cm smaller than diameter a. As a result, the nominal intermediate distance 30 of the inner wall 24 and outer wall 22 of the first flow chamber is 23 1 cm. There is also a difference of 2 cm between the diameter c of the outer wall 26 of the second flow chamber 27 and the diameter d of the inner wall 28 of the second flow chamber 27, so that the nominal intermediate distance 31 is also 1 cm.

The four nested chambers 23, 25, 27, 29 are clearly distinguishable. With decreasing diameter the first flow-through chamber 23, the heating chamber 25, the second flow-through chamber 27 and the core chamber 29. In the embodiment shown, all four chambers 23, 25, 27, 29 are concentric.

Claims (13)

Conclusions A flow-through heater for heating a liquid medium, comprising: — a cylindrical housing, which nested, adjacent and in decreasing outer circumference successively comprises a first flow-through chamber, a heating chamber, a second flow-through chamber and a core chamber, which chambers are preferably arranged concentrically and wherein adjacent chambers have a shared chamber wall, wherein the first and the second flow-through chambers comprise a connection side adjacent to a first side of the cylindrical housing; — at least one heating element, preferably three heating elements, arranged in the heating chamber; - a connecting manifold arranged on a second side located in axial direction opposite the first end of the cylindrical housing, which connecting manifold hydraulically connects the sides located in axial direction opposite the connection sides of the flow chambers; - a first and a second connection opening for coupling to a supply line and a discharge line; - a head manifold, which comprises the first connection opening and the second connection opening and which head manifold hydraulically connects the first and second connection opening to the connection side of the first and the second flow-through chamber, respectively. The flow-through heater of claim 1, wherein at least one core heating element is disposed in the core chamber. The flow-through heater of claim 1 or 2, wherein the header manifold includes at least one heating element holder. The flow-through heater according to any one of the preceding claims, wherein at least a raw vacuum prevails in the heating chamber. The flow-through heater according to any one of claims 1 to 3, wherein the heating chamber is filled with an inert gas. ©. The flow-through heater according to any one of the preceding claims, wherein at least a rough vacuum prevails in the core chamber. The flow-through heater according to any one of claims 1 to 5, wherein the core chamber is filled with an inert gas. The flow-through heater according to any one of claims 1 to 5, wherein the core chamber is open near the second side. The flow-through heater according to any one of the preceding claims, wherein the cylindrical housing has a height measured in the axial direction in the range 30-40cm, preferably 38cm. The flow-through heater according to any one of the preceding claims, wherein the first flow-through chamber has an outer diameter in the range 18-22cm, preferably 20cm. The flow-through heater according to any one of the preceding claims, wherein the outer diameter of the heating chamber is 2cm smaller than the outer diameter of the first flow-through chamber. The flow-through heater according to any one of the preceding claims, wherein the inner diameter of the second flow-through chamber is 2cm smaller than the inner diameter of the heating chamber. The flow-through heater according to any one of claims 1-11, wherein the volume of the first flow-through chamber is equal to the volume of the second flow-through chamber.