HU187948B - Hot water producing system - Google Patents

Abstract

1. Hot water producing apparatus comprising a compressor (2), a first heat exchanger (6) and a second heat exchanger (11) connected to a reverse cooling device (4), a cooling water circuit (5, 10, 17) including the compressor (2), the primary side of the first heat exchanger (6), the second heat exchanger (11) and a back cooler (18), and a warm water circuit (8, 21) including the secondary side of the first heat exchanger (6), which warm water circuit is provided with a warm water store (3) and a third heat exchanger (22) switched parallel to the first heat exchanger (6) and heated electrically in dependency from the wanted temperature, wherein the first, second and third heat exchanger (6, 11, 22) as well as the back cooler and the conduits of the cooling water circuit and the warm water circuit connecting them are forming a structural unit contained in a container (1) the walls of which are provided with connecting pieces (I-VIII) for the compressor (2), the warm water store (3) and the reverse cooling device (4), all of which are positioned outside of the container (1).

Description

The present invention relates to a hot water production system comprising a water-cooled compressor, an electric heat exchanger and further heat exchangers connected to the water-cooled compressor.

In recent years, the energy situation worldwide has become increasingly difficult. The overall goal is to look for solutions that save energy and save energy. waste energy that has been lost so far is being utilized. These energies are usually generated during the operation of technologies and production equipment, at different temperature levels and in different transmission media.

In countries where industry consumes a significant proportion, 10-20%, of the electricity used by industry to produce compressed air, converting the compaction into heat saves significant energy.

Another remarkable area of savings when using nighttime electricity in a heat storage system. However, this requires that the core and consumer networks are capable of transmitting adequate power.

In recovering the heat content of the compressed air, it has been found that in conventional compressor cooling water systems, the cooling water outlet temperature can be approximately doubled and can approach 100 ° C. This difference in temperature, in turn, already allows the use of special heat exchangers to recover about 80% of the heat content of the cooling water. However, a single piping and equipment system has not been developed, but is always attached to a compressor that is usually installed earlier, either locally, using the capabilities of an existing building, or by creating a new building section.

The production of hot water using night-time electricity is well-known in heat-insulated hot water storage tanks with a limited volume, 50-2001 and a limited capacity, at 2 kW.

It is an object of the present invention to provide a hot water production system that combines the utilization of waste heat from compressors with the use of night-time electricity while providing a rapid installation capability.

According to the present invention, this object is achieved by a hot water production system in which the mechanical and electrical equipment of the system is assembled in a container, except for the water-cooled compressor, the hot water storage and the cooling system, and thus forms a unit, the water-cooled compressor DHW production is automatically connected in series or in parallel depending on the constant temperature of the DHW demand.

Preferably, the water outlet of the water-cooled compressor is connected to the inlet of the first heat exchanger, which leads to the outlet of the heat exchanger or to the hot water tank or the hot water consumer, and the electric heat exchanger is connected to the outlet from the outlet of the first heat exchanger before the boiler is branched off, and all heat exchangers are automatically controlled as a function of the constant temperature of the hot water demand. Preferably, the temperature scales of the produced, i.e. utilized, hot water are constant regardless of the mode of operation of the compressor (s).

The advantages of the hot water production system according to the invention are as follows:

- manufactured locally, even in large series;

- Container construction makes it easy to transport the equipment safely;

- the container is easy to install on a simple flat surface or concrete blocks;

- the containerized equipment can be installed immediately after the pipe connections and electrical cable connections are made;

- HVAC and electrical installations do not require a separate building;

- the cooling water system of a compressor or compressor plant becomes completely closed, so that no limescale is formed in the compressors and virtually no additional water is required;

- waste recovered from cooling water113 whose heat content has previously been discharged into the sewage system or into the atmosphere. This recovered hot water can be used primarily for domestic hot water but also for heating purposes with an efficiency of less than 80%;

- supply of domestic hot water at industrial scale using night-time electricity;

- The electric-to-water heat exchanger is designed to provide frost protection for the entire unit and the compressors connected to it during shutdown days with minimal energy input, thus eliminating the need for operational start-up, the compressors and the heat recovery system being immediately operational.

The invention will now be described in more detail with reference to the drawing, which shows a circuit diagram of an exemplary embodiment of a hot water production system according to the invention.

Outside the container 1, which is represented by a dashed line in the drawing, there is a water cooling s 2 compressor, a hot water storage tank 3 and a cooling system 4. Compressor 2 is connected via line 5 to first heat exchanger 6. A pump 7 is connected to the other side of the heat exchanger 6, which is connected to the water network 9 via a pipe 8. The heat exchanger 6 is connected in series 10 with a second heat exchanger II. The other side of the heat exchanger 11 is connected to the water pool 12 of the cooling system 4 by a pipeline 13 into which a pump 14 is installed. 15 pipelines lead from the All heat exchanger to the water basin. Cooling of the cooling system 4 is provided by the cooling tower 16.

From the second heat exchanger 11, a line 17 is led back to the compressor 2 by interposing the aftercooler. The condenser 18 receives the compressed air from the compressor via conduit 19, which exits the condenser through conduit 20.

21 of the first 6 heat exchangers lead to hot water consumers.

An electric heat exchanger 22 is inserted between the conduits 8 and 21 in front of the hot water storage tank 3. All heat exchangers 6, 11 and 22 are automatically actuated by the controls 23 and 24. Controller 24 actuates motor valve 25.

The hot water production system according to the invention operates as follows:

Water-cooled electric motor driven by 2 compressors

-2187 948 charging electricity from the grid.

The water discharged from the compressor 2 through the pipe 5 is approx.

At temperature C, it enters the first heat exchanger 6, from where it passes through conduit 21 for approx. Discharges to consumers at 45 ° C. On the other side of the first heat exchanger 6, the cold water coming from the water network 9 via the pipeline 8 is circulated by the pump 7. The water at 45 ° C leaving the heat exchanger 6 passes through the pipeline 10 to the second heat exchanger 11, from where it reaches approx. At 35 ° C, it is returned to the compressor 2 via line 17. The water is cooled on the second heat exchanger 11 from the water pool 12 of the cooling system 4 by means of the pump 14 via the cooling water circulated through the pipeline 13. The water flowing from the heat exchanger All goes back through the pipeline 15 to the water basin 12. 15

Depending on the position of the pump 26 in the pipeline 17, depending on the position of the motorized valve 25 also in this pipeline, which is actuated by the controller 24, the water output at pipeline 5 circulates to 90 ° C through the aftercooler 18 and across. In this case, the heat exchanger 6 does not have a heat exchange, all cooling of the compressor cooling water is done by an all heat exchanger.

The electric heat exchanger 22 comes into operation when the temperature of the water discharged to the consumer through the pipeline 21 is not the desired temperature.

3 hot water tanks connected to the external network and 7,

The calculation amount of the pumps 14, 26 and 27 is selected or adapted to the intermittent hot water intake so that the heat exchanger 6 always receives cold tap water.

At night, independent of or in parallel with the operation of the compressor 2, the electric heat exchanger 22 is switched on, producing hot water within the power range.

The connection points for the hot water system to the container are as follows: at point I, the cooling water enters from the compressor 2 into the container; II. at the point, the domestic hot water exits the container; III. point of entry of cold water into the container; ARC. at the point the cold water enters the compressor 2; At point V the compressed air enters the container, VI. at a point, the compressed air exits the cocoaener; VII. point, the cooling water of the heat exchanger 11 enters the container and Vili. At point 1, the heat exchanger 11 coolant exits the container.

Claims (3)

A hot water production system comprising a water-cooled compressor, an electric heat exchanger and further heat exchangers connected to the water-cooled compressor, characterized in that the mechanical and electrical equipment of the system is a water-cooled compressor (2), a hot water tank (3); except for the cooling system (4), they are mounted in a common frame, container (1) and thus form one unit, the hot water production of the water-cooled compressor (2) and the hot water production of the electric heat exchanger are automatically connected in series or parallel. Embodiment of the hot water production system according to claim 1, characterized in that the water outlet of the water-cooled compressor (2) is connected to the inlet of a first heat exchanger (6), leading to the outlet of the heat exchanger (6) or the hot water tank the first heat exchanger (6) being connected to the second heat exchanger (11) having an outlet to the cooling system (4) and the second heat exchanger (11) being fed back to the compressor (2) via the compressed air aftercooler (18) And (22) is connected to a discharge line from the outlet of the first heat exchanger (6) before branching the hot water tank (3), and each heat exchanger (6, 11, 22) is automatically controlled according to the constant temperature of the hot water demand. Embodiment of the hot water production system according to claim 1 or 2, characterized in that the temperature of the hot water produced, i.e. utilized, is constant irrespective of the mode of operation of the compressor (s) (2).