NL2034655B1 - COOLING SYSTEM AND METHOD FOR COOLING A ROOM WITH COOLING ELEMENTS WITH PHASE CHANGE MATERIAL - Google Patents

Abstract

The invention relates to a cooling system (1) for cooling a space (100). The cooling system comprises rows of cooling elements (3) with phase change material, first air circulation means (5) for generating an external air flow (A) between the environment and the cooling system and second air circulation means (4) for generating an internal air flow (B) between the space and the cooling system. The cooling system further comprises external air flow distribution means (21, 81) which are designed to guide the external air flow along a first surface of the cooling elements and internal air flow distribution means (22, 82) which are designed to guide the internal air flow along a second surface of the cooling elements.

Description

COOLING SYSTEM AND METHOD FOR COOLING A ROOM WITH

COOLING ELEMENTS WITH PHASE CHANGE MATERIAL

The invention relates to a cooling system for cooling a space, for example an equipment room, in which the cooling system comprises a housing in which a number of cooling elements are accommodated, which cooling elements are provided with a first and a second surface and in which phase change material is incorporated in each cooling element, in which the cooling system further comprises air circulation means for generating an air flow along the first and the second surface of the cooling elements.

A cooling system according to the preamble is known in the field and uses generally plate-shaped cooling elements containing phase change material for the storage and release of thermal energy. In interaction with the Juchi current, the phase change material will absorb latent heat by transitioning from solid to liquid, after which this heat is released again upon solidification.

Phase change material is also referred to as phase change material (Phase

Change Material, PCM). The well-known cooling system has a much lower electricity consumption than, for example, air conditioning.

The invention aims to improve a cooling system of the type mentioned in the preamble.

The cooling system according to the invention is characterized in that the air circulation means comprise first air circulation means for generating an external air flow between the environment and the cooling system, that the air circulation means comprise second air circulation means for generating an internal air flow between the space and the cooling system, that the cooling system comprises external air flow distribution means, which are connected to the first air circulation means and to the cooling elements, wherein the external air flow distribution means are designed to guide the external air flow along the first surface of the cooling elements, and that the cooling system comprises internal air flow distribution means, which are connected to the second air circulation means and to the cooling elements, wherein the internal air flow distribution means are designed to guide the internal air flow along the second surface of the cooling elements.

The cooling system according to the invention cools the space indirectly with air from the environment of the space (outside air or external air) without mixing outside air with inside air (internal air). The external air flow and the internal air flow remain separate. This results in a lockable, controlled, air-conditioned space, in which technical equipment can continue to function optimally.

According to a practical preferred embodiment of the cooling system according to the invention, the cooling elements are arranged adjacently in one or more rows, in which the first surfaces of the cooling elements in a row face each other and in which the second surfaces of the cooling elements in a row face each other. The external and internal airflow distribution means can be optimally positioned herein in connection with the first and second surfaces, respectively.

The practical preferred embodiment can be expanded as desired by stacking two or more rows of cooling elements on top of each other in one or more columns, wherein the first surfaces of the cooling elements in a column are in line with each other and wherein the second surfaces of the cooling elements in a column are in line with each other.

In a first preferred embodiment of the cooling system according to the invention, the external air flow distribution means comprise first external air flow distribution blocks, which are provided with an external air inlet for connection to the first air circulation means and with recesses for receiving first ends of the cooling elements and with air ducts that connect to the external air inlet and open out next to the recesses. The first external air flow distribution blocks form the entrance to the cooling elements for the external air flow.

In a further elaboration of the first preferred embodiment of the cooling system according to the invention, the internal airflow distribution means comprise first internal airflow distribution blocks, which are provided with an internal air inlet for connection to the second air circulation means and with recesses for receiving first ends of the cooling elements and with air ducts that connect to the internal air inlet and open out next to the recesses. The first internal airflow distribution blocks form the entrance to the cooling elements for the internal airflow.

In an optimal configuration of the cooling system according to the invention, the first external air flow distribution blocks and the first internal air flow distribution blocks are placed alternately.

In a further preferred embodiment of the cooling system according to the invention, the external airflow distribution means comprise second external airflow distribution blocks, which are provided with recesses for receiving second ends of the cooling elements, with external air ducts that start next to the recesses and with an external air outlet that connects to the external air ducts. The second external airflow distribution blocks form the exit for the external airflow from the housing to the environment.

In a further elaboration of the further preferred embodiment of the cooling system according to the invention, the internal airflow distribution means comprise second internal airflow distribution blocks, which are provided with recesses for receiving second ends of the cooling elements, with internal air ducts that start next to the recesses and with an internal air outlet that connects to the internal air ducts. The second internal airflow distribution blocks form the exit for the internal airflow from the housing to the space.

In a further optimal configuration of the cooling system according to the invention, the first external air flow distribution blocks and the first internal air flow distribution blocks are arranged alternately.

In a compact preferred embodiment of the comprehensive cooling system according to the invention, in which the cooling elements are stacked in two or more rows on top of each other in one or more columns, the cooling system further comprises one or more spacers, which are intended for placement between adjacent rows of cooling elements and are designed to guide the external air flow and the internal air flow respectively separately along the first and second surfaces of the cooling elements respectively. Preferably, the spacers are provided for this purpose with a pattern of external air passages and internal air passages.

According to a further elaboration of the compact preferred embodiment of the extensive cooling system according to the invention, the spacers are provided on a first surface with first channels for receiving second ends of the cooling elements and the spacers are provided on a second surface with second channels for receiving first ends of the cooling elements. More preferably, the channels are bounded in the longitudinal direction on one side by a row of external air passages and on the other side by a row of internal air passages.

A complete preferred embodiment of the cooling system according to the invention further comprises a control system for controlling the first and second air circulation means.

The invention also relates to a method for cooling a space, for example an equipment room, comprising the following steps: a) generating an internal air flow between the space and the cooling system; b) guiding the internal air flow along the second surface of the cooling elements; c) generating an external air flow between the environment and the cooling system; and d) guiding the external air flow along the first surface of the cooling elements.

The invention will be explained with reference to the accompanying figures, in which

Figure 1 shows a schematic view of a space containing a first preferred embodiment of the cooling system according to the invention;

Figure 2 shows an exploded view of the cooling system of Figure 1;

Figures 3A to 3C show some of the components from Figure 2 in more detail;

Figures 4A through 4C show some other parts from Figure 2 in more detail; and

Figure 5 shows another part of Figure 2 in more detail.

Figures 1 and 2 show a cooling system 1 according to the invention in a first preferred embodiment, in which the cooling system 1 is intended for cooling a lockable space, such as a technical space or equipment room. Examples of this are a meter room, street cabinet, computer room, battery room, inverter room, boiler room, elevator machine room and the like.

Figure 1 shows a schematic view of a space 100 containing the cooling system 1. Figure 2 shows the cooling system 1 in exploded view.

The cooling system 1 comprises a housing 10, in which a number of cooling elements 3 are accommodated, in each cooling element phase change material is incorporated. The cooling elements 3 are arranged such that air can flow along the cooling elements.

The cooling system 1 comprises first air circulation means 5 for generating an external air flow A with air coming from outside the space 100 along the cooling elements and back outside. The cooling system 1 comprises second air circulation means 4 for generating an internal air flow B with air coming from inside the space along the cooling elements 3 and back into the space. Suitable air circulation means are for example fans.

Optionally, the cooling system comprises first filters 7, which are connected to the first air circulation means 5, and second filters 6, which are connected to the second air circulation means 4.

A control system 2 controls the first and second air circulation means 4, 5. Preferably, the cooling system comprises temperature sensors for this purpose, such as a first temperature sensor (not shown) for measuring the external temperature outside the space 100, a second temperature sensor (S) for measuring the average internal temperature in the space 100, a third temperature sensor for measuring the temperature of the PCM.

In the preferred embodiment shown, the cooling elements 3 are arranged in two or more rows, which are placed one above the other in a column. The cooling elements 3 are generally plate-shaped and have a first surface on one side and a second surface on an opposite side. The cooling elements 3 in each row are placed substantially parallel to each other at some distance from each other and have substantially the same orientation, with the first surfaces of the cooling elements facing each other and the second surfaces of the cooling elements facing each other.

First air flow distribution blocks 20 are connected to the cooling elements 3 in the upper row, which are designed to keep the external air flow A from the first air circulation means 5 and the internal air flow B from the second air circulation means 4 separate and to guide each along a separate part of the surface of the cooling elements 3. Spacers 50 are arranged between the adjacent rows, which are designed to guide the separated external air flow A and the internal air flow B each separately further along a separate part of the surface of the cooling elements 3. Second air flow distribution blocks 80 are connected below the lower row of cooling elements 3, which are designed to guide the external air flow A to the outside and to guide the internal air flow B into the room.

In the first preferred embodiment, the housing 10 comprises a front plate 11 and a rear plate 12, which are interconnected by side plates 14, 18 and 17. The side plates 14 are first side plates, which are attachable to the cooling elements 3 and the first airflow distribution blocks 20. The side plates 16 are intermediate side plates, which are attachable to the cooling elements 3 and the spacers 50. The side plates 17 are second side plates, which are attachable to the cooling elements 3 and the second airflow distribution blocks 80.

Figure 3A schematically shows a series of first airflow distribution blocks 20, which can be mounted on top of the stack of cooling elements 3. In the preferred embodiment shown, there are two types of first airflow distribution blocks. A schematic view of a first, external airflow distribution block 21 (type 1) is shown in Figure 3B. Figure 3C schematically shows a first, internal airflow distribution block 22 (type 2). The first, external airflow distribution block 21 and the first, internal airflow distribution block 22 have many similarities. Both are generally plate-shaped and have an air inlet 23 and 24, respectively, at the top. At the bottom, both are provided with recesses 25 and 26, respectively, for receiving the top sides of the plate-shaped cooling elements 3. The external air inlet 23 distributes the external air via a number of external air ducts 27 over several external air duct mouths 29 next to the recesses 25. In the preferred embodiment shown, an air duct mouth 29 is located after every odd number of recesses 25. The internal air inlet 24 distributes the internal air via a number of internal air ducts 28 over several air duct mouths 30 next to the recesses 26. In the preferred embodiment shown, an air duct mouth 30 is located after every even number of recesses 26.

The shape of each recess 25 and 26, respectively, is complementary to the shape of the top of each cooling element 3. In the preferred embodiment shown, the shape of the recesses 25 and 26, respectively, is generally arcuate.

In the preferred embodiment shown, the first, external airflow distribution blocks 21 and the first, internal airflow distribution blocks 22 are alternately positioned in the series of first airflow distribution blocks 20.

Figure 4A schematically shows a series of second airflow distribution blocks 80, which can be mounted at the bottom of the stack of cooling elements 3. In the preferred embodiment shown, there are two types of second airflow distribution blocks. A schematic view of a second, external airflow distribution block 81 (type 3) is shown in Figure 4B. Figure 4C schematically shows a second, internal airflow distribution block 82 (type 4).

The second, external airflow distribution block 81 and the second, internal airflow distribution block 82 have many similarities. Both are generally plate-shaped and are provided with recesses 85 and 86 at the top, respectively, for receiving the undersides of the plate-shaped cooling elements 3.

Both have an air outlet 83 and 84 on one side, respectively. Several external air duct mouths 89 run next to the recesses 85, which are connected to a number of external air ducts 87. In the preferred embodiment shown, an air duct mouth 89 is located after every odd number of recesses 85. The air ducts 87 end in the external air outlet 83. Several internal air duct mouths 90 run next to the recesses 86, which are connected to internal air ducts 88. In the preferred embodiment shown, an air duct mouth 90 is located after every even number of recesses 86. The air ducts 88 end in the internal air outlet 84.

The shape of each recess 85 and 86, respectively, is complementary to the shape of the underside of each cooling element 3. In the preferred embodiment shown, the shape of the recesses 85 and 86, respectively, is generally arcuate.

In the preferred embodiment shown, the second, external airflow distribution blocks 81 and the second, internal airflow distribution blocks 82 are alternately disposed in the series of second airflow distribution blocks 80.

Figure 5 shows a spacer 50 from figure 2 in more detail. The spacer 50 is generally plate-shaped and is provided on a first surface with first grooves 55 for receiving the undersides of the plate-shaped cooling elements 3 from a row.

On a second surface, the spacer 50 is provided with second channels 56 for receiving the top sides of the plate-shaped cooling elements 3 from the adjacent row.

Both the first and second surfaces are provided with upright support members 53, which are located between the adjacent gutters 55, 56. Each spacer is further provided with external air passages 59 and internal air passages 60. The external air passages 59 are substantially in line with the external air duct mouths 29 and the external air duct mouths 89. The internal air passages 60 are substantially in line with the internal air duct mouths 30 and the internal air duct mouths 90.

In the preferred embodiment shown, the ducts 55, 56 are bounded in the longitudinal direction on the one hand by a row of external air passages 59 and on the other hand by a row of internal air passages 60. The external air passages 59 and the upright wall parts 53 are arranged alternately in a respective row. The internal air passages 60 and the upright wall parts 53 are also arranged alternately in a respective row. In the transverse direction, the upright wall parts 53 are also always located between two external air passages 59 and between two internal air passages 60, respectively, depending on the point of view.

According to the inventive idea, the external and internal airflow distribution means, optionally in cooperation with the spacers, define a pattern of separate external and internal airflows, in which the external airflow flows past each cooling element on one side and the internal airflow flows past the cooling element on the other side.

Examples of suitable PCM are inorganic materials, for example water mixed with salts. An example of a suitable salt is calcium chloride. The composition of the PCM can be chosen so that it melts/solidifies at a desired target temperature in the room, for example 27 degrees Celsius.

The method according to the invention for cooling a space, for example an equipment room, by means of a cooling system comprising a number of cooling elements comprising phase change material and provided with a first and a second surface, comprises the following steps: a) generating an internal air flow between the space and the cooling system; and b) guiding the internal air flow along the second surface of the cooling elements; c) generating an external air flow between the environment and the cooling system; and d) guiding the external air flow along the first surface of the cooling elements.

When the average internal temperature in the space rises above the target temperature, steps a) and b) cause the phase change material to absorb the heat from the space and cool the space. The phase change material melts and stores the heat. This heat storage is temporary.

As soon as the external temperature outside the room drops below the solidification temperature, steps c) and d) ensure that the phase change material releases the heat to the environment. The cooler outside air solidifies the phase change material. This process can repeat itself indefinitely.

The method according to the invention preferably uses the day-night rhythm, with steps a) and b) taking place during the day and steps c) and d) at night.

In the preferred embodiment shown, the cooling elements 3 have a substantially vertical orientation, as do the external and internal airflow distribution blocks 20, 80. The spacers 50 have a substantially horizontal orientation.

It should be noted that an alternative orientation of the cooling elements 3 and airflow distribution blocks 20, 80 is possible, for example horizontally, in combination with a vertical orientation of the spacers 50. In that case, the terms “top” and “bottom” in the description of the figures of the preferred embodiment should be replaced by “inlet side” and “outlet side”. The external and internal airflow distribution blocks are then placed against the cooling elements on either side.

In the preferred embodiment shown, the external airflow A and the internal airflow B flow substantially parallel along the cooling elements in a substantially equal flow direction. This is not necessary. The direction of the external airflow A and the internal airflow B along the cooling elements can also be opposite. The flow direction of the external airflow A can be at an angle to the flow direction of the internal airflow B.

In addition, the first and/or second air circulation means may also comprise suction means instead of blowing fans.

The invention is therefore not limited to the preferred embodiment described and shown, but extends to any embodiment that falls within the scope of protection as defined in the claims and viewed in the light of the foregoing description and accompanying drawings.

Claims (15)

CONCLUSIONS 1. Cooling system for cooling a space, for example an equipment room, wherein the cooling system comprises a housing in which a number of cooling elements are accommodated, which cooling elements are provided with a first and a second surface and in which phase change material is incorporated in each cooling element, wherein the cooling system further comprises air circulation means for generating an air flow along the first and the second surface of the cooling elements, characterized in that the air circulation means comprise first air circulation means for generating an external air flow between the environment and the cooling system, that the air circulation means comprise second air circulation means for generating an internal air flow between the space and the cooling system, that the cooling system comprises external air flow distribution means, which are connected to the first air circulation means and to the cooling elements, wherein the external air flow distribution means are adapted to guide the external air flow along the first surface of the cooling elements, and that the cooling system comprises internal air flow distribution means, which are connected to the second air circulation means and to the cooling elements, wherein the internal air flow distribution means are adapted to guide the external air flow along the second surface of the cooling elements guide the internal air flow. 2. The cooling system of claim 1, wherein the cooling elements are arranged adjacently in one or more rows, wherein the first surfaces of the cooling elements in a row face each other and wherein the second surfaces of the cooling elements in a row face each other. 3. The cooling system of claim 2, wherein two or more rows of cooling elements are stacked on top of each other in one or more columns, wherein the first surfaces of the cooling elements in a column are in line with each other and wherein the second surfaces of the cooling elements in a column are in line with each other. 4. A cooling system as claimed in claim 1, 2 or 3, wherein the external airflow distribution means comprise first external airflow distribution blocks having an external air inlet for connection to the first air circulation means and recesses for receiving first ends of the cooling elements, and air ducts connecting to the external air inlet and opening adjacent to the recesses. 5. A cooling system according to any preceding claim, wherein the internal airflow distribution means comprise first internal airflow distribution blocks having an internal air inlet for connection to the second air circulation means and recesses for receiving first ends of the cooling elements, and air ducts connecting to the internal air inlet and opening adjacent to the recesses. 6. The cooling system of claim 5 and 8, wherein the first external airflow manifolds and the first internal airflow manifolds are arranged alternately. 7. A cooling system according to any preceding claim, wherein the external airflow distribution means comprises second external airflow distribution blocks having recesses for receiving second ends of the cooling elements, external air ducts beginning adjacent to the recesses and an external air outlet connecting to the external air ducts. 8. A cooling system as claimed in any preceding claim, wherein the internal airflow distribution means comprises second internal airflow distribution blocks having recesses for receiving second ends of the cooling elements, internal air channels beginning adjacent to the recesses and an internal air outlet connecting to the internal air channels. 9. The cooling system of claim 7 and 8, wherein the second external airflow manifolds and the second internal airflow manifolds are arranged alternately. 10. Cooling system according to any of the preceding claims 3-9, wherein the cooling system further comprises one or more spacers, which are intended for placement between adjacent rows of cooling elements and are arranged to guide the external air flow and the internal air flow respectively separately along the first and second surfaces of the cooling elements respectively. 11. The cooling system of claim 10, wherein the spacers are provided with a pattern of external air passages and internal air passages. 12. The cooling system of claim 10 or 11, wherein the spacers on a first surface are provided with first channels for receiving second ends of the cooling elements and wherein the spacers on a second surface are provided with second channels for receiving first ends of the cooling elements. 13. Cooling system according to claim 11 and 12, wherein the channels are bounded in the longitudinal direction on one side by a row of external air passages and on the other side by a row of internal air passages. 14. A cooling system according to any preceding claim, wherein the cooling system further comprises a control system for controlling the first and second air circulation means. 15. Method for cooling a space, for example an equipment room, by means of a cooling system comprising a number of cooling elements comprising phase change material and having a first and a second surface, comprising the following steps: a) generating an internal air flow between the space and the cooling system; b) guiding the internal air flow along the second surface of the cooling elements; c) generating an external air flow between the environment and the cooling system; and d) guiding the external air flow along the first surface of the cooling elements.