SE527638C2 - Stabiliser for heat exchanger and heat exchange system which incorporates it involve heating of hot water using remote heat - Google Patents

Abstract

The stabiliser for a heat exchanger and a heat exchanger system which incorporates it involve heating of hot water using remote heat. The heat exchanger has channels for first and second media and a regulating device which controls the temperature in the second medium to a required level after heating. The stabiliser is a further heat exchanger which contains at least one first phase-changing stabilising medium with a melting point somewhat higher than the required temperature. The stabiliser is connected to the outlet from the heat exchanger for the second medium. The stabiliser contains wax or similar. The stabiliser can therefore eliminate undesirable temperature peaks arising from heat pulses in the system.

Description

527 638 2 slightly above the desired temperature. The stabilizer can thereby cut unwanted temperature peaks resulting from heat pulses in the system. The stabilizer can be supplemented with additional wax or the like with a melting point slightly below the desired temperature to also cut unwanted cold pulses.

Thus, the invention provides a stabilizer for heat exchangers. This heat exchanger has channels for a first medium and a second medium, the first medium being intended to supply heat to the second medium, and a control equipment arranged to control the temperature in the second medium to a desired temperature after heating.

According to the invention, the stabilizer is an additional heat exchanger which contains at least one first stabilizing medium with a melting point slightly higher than the desired temperature and the stabilizer is arranged to be connected to the outlet of the heat exchanger for the second medium.

The stabilizer may also contain a second stabilizing medium having a melting point slightly lower than the desired temperature.

The heater also provides a heat exchanger system that includes such a stabilizer.

The invention is defined in appended claims 1 and 12, while embodiments are specified in the dependent claims.

Brief Description of the Drawings The invention will be described in detail below with reference to the accompanying drawing, the only one of which is a schematic view of a heat exchanger system containing a stabilizer in accordance with the invention.

Detailed Description of Preferred Embodiments As mentioned in the introduction, the invention relates to a stabilizer for heat exchangers. Heat exchangers are generally known devices for heat exchange between different media. The invention can, for example, be applied to plate heat exchangers of a fully soldered type.

Such heat exchangers consist of plates with a pattern of grooves as well as connections for inlet and outlet for two media. The plates are placed in a package and soldered together into a fixed unit. Separate channels are then formed for the two media circulating towards each other between alternating pairs of plates. This technique is generally known and is therefore not described further here.

I fi g. 1 shows a schematic view of a heat exchanger system for heating hot water 4 by means of hot water 3 from a micro-heating network. A heat exchanger 2 has an inlet 3I and an outlet 30 for the district heating water and an inlet 41 and an outlet 40 for the hot water. The outlet of the water water is regulated with a tap valve 8.

Valve 8 is usually extreme and not part of the heat exchanger, typically a number of 527 638 3 hot water taps that are found in different places in a property. It will be appreciated that the hot water is actually cold, or at least has a lower temperature, at the inlet 41 and is heated by the heat exchanger on the way to the outlet 40.

The incoming district heating water usually has a temperature around 100 ° C.

The temperature can be both higher and lower depending on the outdoor temperature, dimensioning data for the current district heating system and other conditions.

The supply of the district heating water is controlled by a valve 7 which is preferably mounted in the district heating water return line fi from the heat exchanger 2 or in the district heating water supply line to the heat exchanger 2. The valve 7 can alternatively be integrated with the heat exchanger. a temperature sensor 6 which can be mounted in connection with the outlet 40 of hot water from the heat exchanger 2. A control equipment 5 receives the signal fi from the sensor 6 and controls the valve 7, as indicated by dashed lines.

The district heating water should flow through the heat exchanger, partly continuously when the tap 8 is open or when a possibly connected hot water circulation circuit 9 is in driñ ßr to heat the hot water and partly intermittently, if the hot water circulation circuit 9 is missing or not in dri fi, and when the tap 8 is closed to provide a keeping of the hot water in the heat exchanger, so that even in that case there is direct access to hot water when the tap 8 is opened. On the other hand, it is important that the district heating valve 7 reacts directly to temperature changes in the hot water and closes quickly when the tap 8 is closed. If the district heating valve 7 continues to be too open, an overheating of the hot water occurs, more or less severe depending on how quickly the scar heating valve 7 is then closed.

Should the tap 8 then be opened again, there is a risk of scalding. Normally, the outgoing hot water should never have a temperature higher than about 55 ° C. A late closing of the valve 7 also leads to an increased energy consumption and can cause problems with limescale deposits in the heat exchanger.

It is normally desired that the hot water coming to the tap should maintain a temperature of about 53 or 55 ° C. In Sweden, the temperature may currently be a maximum of 65 ° C.

The technique described above is conventional. When the tap 8 is opened, it may happen that the hot water is too cold if the control equipment 5 reacts slowly. However, this is more annoying than dangerous.

After a withdrawal of hot water from the tap 8, the heat exchanger 2 is more or less filled with hot district heating water and when the tap is closed, an overheating of the hot water can occur, especially if there is a delay before the valve 7 is closed.

If the water tap 8 is opened again, a heat pulse occurs, ie a quantity of water is passed through which has a higher temperature, eg 75 ° C. This heat pulse entails a risk of scalding and should therefore be eliminated.

The present invention solves this problem with the aid of a so-called stabilizer. The generator shows a stabilizer 1 placed in the hot water circuit after the district heat exchanger 2. The stabilizer comprises an additional heat exchanger. In the fi clock, stabilizer 1 has an excessive size compared to the district heat exchanger 2.

The stabilizer 1 has inlet 11 and outlet 110 for the heated hot water 4. The surrounding channels in the stabilizer 1 are filled with a phase-changing medium, e.g. wax, paraffin or glycerin or the like. It is currently believed that wax is used. The wax has a melting point around, for example, 58 ° C, i.e. preferably slightly higher than the desired temperature of 55 ° C but at the same time considerably lower than a dangerous temperature level. The wax does not have to circulate, it is sufficient for the stabilizer connections 10 for this circuit to be sealed, however, with the required expansion space for the molten wax. The hot water flowing through the stabilizer l is thus heat exchanged for wax in phase conversion fi from solid to liquid phase and vice versa.

If a heat pulse is received with the hot water in the stabilizer, a heat exchange takes place towards the wax. The wax melts while absorbing heat. However, the wax does not increase temperature above 58 ° C until all the wax has melted. A lot of energy is needed for the phase transition itself. At a normal heat pulse of approx. 75 ° C, a maximum peak of S8.3 ° C is measured in a test in the hot water fi without the stabilizer.

With knowledge of a normal heat pulse size, ie. ternperatum level and amount of water, you can dimension the amount of wax. An amount of a couple of 100 grams of wax has proven to be sufficient for a smaller building's heating equipment.

When the heat pulse is over, tempered hot water, 55 ° C, normally flows through the stabilizer if the withdrawal continues. If there is a hot water circulation circuit (VV C) 9, this also continues to circulate the hot water even when the tap 8 is closed. The wax then solidifies while emitting heat. However, this energy is released at 58 ° C and can not cause any troublesome overheating. (The overheating in the district heat exchanger is caused by the district heating water, which can be about 100 ° C or higher.) The stabilizer thus evens out a too low temperature if the hot water should become slightly too cold due to unstable regulation.

The stabilizer 1 can therefore also be used to solve the problem of too cold water, a so-called "cold pulse". An additional wax or the like is then used in Stabilizer 1. The stabilizer then contains a high-temperature wax against heat pulses and a low-temperature wax against cold pulses. The low temperature wax has a melting point below the desired temperature, eg at 52 ° C. If there is a hot water circulation 9, the hot water always maintains the desired temperature 55 ° C (until new colder water is released at the inlet 4I when the tap 8 is opened).

The low temperature wax is then melted. If a cold pulse enters with the hot water in the stabilizer 527 658, then a heat exchange takes place which strives to cool the low temperature wax below its melting point. The wax solidifies while emitting heat at its melting point of 52 ° C.

The wax does not reduce its temperature until all the wax has solidified and in the meantime emits energy in the phase transition. The energy is sufficient to eliminate or reduce the cold pulse.

The high-temperature wax and the low-temperature wax are suitably arranged separately in different sections IA and IB in the stabilizer 1. For example, the stabilizer is divided into two series-connected strips with the low-temperature wax in section IB closest to the hot water outlet and the high-temperature wax in section 1A closest to the inlet III. The lanes can be separated by a physical wall. It is also possible to exclude the wall and allow the high-temperature wax and the low-temperature wax to mix slightly with each other near the boundary between them. Additional stabilizing phase transformation temperatures may occur in the boundary layer.

The amount of low temperature wax may be the same or less than the amount of high temperature wax, e.g. about 20 to 100 grams, but can also be completely excluded.

The invention enables a simpler and cheaper control equipment with lower requirements for temperature stability to be used without the risk of scalding.

A person skilled in the art realizes that the heat exchanger's design, choice of heat exchanger type, heat exchanger connections and valves, etc. can be varied.

The scope of the invention is limited only by the following claims.

Claims (14)

10 15 20 25 30 35 527 638 6 PATENT REQUIREMENTS A heat exchanger stabilizer, the heat exchanger (2) having channels for a first medium and a second medium, the first medium (3) being intended to provide heat to the second medium (4), and a control equipment arranged to control the temperature in the second medium (4) is heated to a desired temperature, characterized in that the stabilizer (1) is an additional heat exchanger containing at least a first stabilizing medium with a melting point slightly higher than the desired temperature and that the stabilizer (1) is arranged to be connected to the output (40) of the heater (2) for the second medium (4). Stabilizer according to claim 1, characterized in that the stabilizer (1) contains a second stabilizing medium with a melting point slightly lower than the desired temperature. Stabilizer according to claim 2, characterized by separate compartments (IA, IB) ßr the two stabilizing media. Stabilizer according to claim 3, characterized in that the compartment (IA) of the stabilizing medium with the higher melting point is located closest to the outlet (40) of the heat exchanger (2) for the second medium (4). Stabilizer according to one of the preceding claims, characterized in that the stabilizing medium is wax. Stabilizer according to one of the preceding claims, characterized in that the first stabilizing medium is wax with a melting point of around 55 ° C. Stabilizer according to one of Claims 2 to 6, characterized in that the second stabilizing medium is wax with a melting point of around 52 ° C. Stabilizer according to one of the preceding claims, characterized in! in that the amount of the first stabilizing medium is adapted to an expected maximum heat pulse. Stabilizer according to any one of the preceding claims, characterized in that the amount of the first stabilizing medium is about 100 grams. Stabilizer according to one of the preceding claims, characterized in that the amount of the second stabilizing medium is adapted to an expected maximum cold pulse. 10 15 527 638 Stabilizer according to any one of the preceding claims, characterized in that the amount of the second stabilizing medium is about 20 to 100 grams. A heat exchanger system comprising a heat exchanger (2) having channels for a first medium (3) and a second medium (4), the first medium (3) being intended to provide heat to the second medium (4), a control equipment (5 ) arranged to control the temperature in the second medium (4) after heating to a desired temperature, characterized in that it comprises a stabilizer (1) according to any one of claims 1 to 1 1. Heat exchanger system according to claim 12, characterized in that inlets (31) and outlets (30) for the first medium (3) are arranged to be connected to a scar heating network and that inlets (41) and outlets (40) for the second medium (4) ) are arranged to be connected to a hot water circuit which contains at least one valve (8) for regulating the withdrawal of hot water and thus the supply of the second medium (3) through the heat exchanger (2). Heat exchanger system according to claim 13, characterized in that the hot water circuit also contains a hot water circulation circuit (9).