DE202018000758U1 - Heat exchange device for controlling the water temperature - Google Patents

Abstract

A heat exchange apparatus for controlling the water temperature, comprising a main body (1), a thermoelectric cooler (2) and a cooling unit (3), one side of the main body (1) being open, the main body (1) having at least one open side Space (11) through which flows the water (A), wherein on the space (11) of the main body (1) of the thermoelectric cooler (2) is arranged, whereby the space (11) of the main body (1) with the heat receiving surface (21) of the thermoelectric cooler (2), wherein the cooling unit (3) is connected to the heat discharge surface (22), wherein the main body (1) on the same side or on both sides of two tubes (12) for water inlet and a water outlet, wherein a pump (4) the water (A) through a pipe section (12) of the main body (1) in the space (11) of the main body (1) promotes the water (A) in the main body (1) directly with the heat receiving surface ( 21) of the thermoelectric cooler (2), whereby the temperature of the water (A) of the heat receiving surface (21) of the thermoelectric cooler (2) is reduced, wherein the heat of the heat transfer surface (22) of the thermoelectric cooler (2) the cooling unit (3) is passed, which performs a heat exchange with the air.

Description

BACKGROUND OF THE INVENTION

1. Field of the invention:

The invention relates to a heat exchange device for controlling the water temperature, in particular for use on aquarium and suitable for seawater system.

2. Description of the relevant prior art:

The conventional device for controlling the water temperature in the aquarium usually has a hollow body made of metal, a thermoelectric cooler, a set of cooling fins and a fan. A pump delivers the water from the aquarium through a hose into the hollow body of metal. The thermoelectric cooler absorbs the heat of the hollow body. The hollow body absorbs the heat of the water. The heat on the heat-dissipating surface of the thermoelectric cooler is directed to the set of cooling fins. The fan dissipates the heat of the cooling finset. Here, the heat of the water is passed indirectly through the hollow body. In addition, a bonding layer exists between the hollow body and the thermoelectric cooler, so that the efficiency of the heat conduction is not good. In summer, the ambient temperature is higher than the water temperature in the aquarium. The vessel and the water can absorb the ambient heat. The hollow body can also absorb the ambient heat, whereby the temperature of the hollow body increases. As a result, the hollow body can not significantly reduce the temperature of the water flowing through. In order to increase the heat capacity of the heat receiving surface of the thermoelectric cooler, the performance of the thermoelectric cooler is increased. In this case, the heat of the heat transfer surface of the thermoelectric cooler can not be effectively derived from the finset and the fan. Therefore, the water temperature in the aquarium can not be effectively reduced. If the water in the aquarium is seawater, the hollow body of metal may corrode, thereby shortening the life and reducing the efficiency of heat exchange. In addition, the conventional solution has high costs and low production speed.

SUMMARY OF THE INVENTION

The invention relates to a heat exchange device for controlling the water temperature, in particular for use on aquarium and suitable for seawater system, comprising a main body, which is made of material with a low coefficient of thermal conductivity, a thermoelectric cooler and a cooling unit. The main body has a space for the water and on the same side or on both sides of two tubes for water inlet and a water spout on. One side of the main body is open. The open side of the main body is connected to the heat receiving surface of the thermoelectric cooler. The cooling unit is connected to the heat delivery surface. The cooling unit includes a heat conducting element and an air cooling element. The pump conveys the water into the space of the main body through a hose connected to a pipe section of the main body. The water in the main body directly contacts the heat receiving surface of the thermoelectric cooler, thereby reducing the temperature of the water from the heat receiving surface of the thermoelectric cooler. The heat of the heat delivery surface is directed to the cooling unit, which performs heat exchange with the air. The main body is made of low thermal conductivity coefficient material such as metal, plastic, glass fiber or composite material. As a result, the water in the main body can not be easily influenced by the ambient temperature, so that corrosion of the main body is avoided. Therefore, the life is prolonged and the working efficiency of the thermoelectric cooler is increased. Since an influence of the main body on the ambient temperature is avoided and the working efficiency of the thermoelectric cooler is increased, the highest performance can be reduced, so that the costs are lower and power saving can be achieved.

The invention has for its object to provide a heat exchange device for controlling the water temperature, wherein the water in the main body is directly in contact with the heat receiving surface of the thermoelectric cooler, whereby the temperature of the water is reduced from the heat receiving surface of the thermoelectric cooler, so that the efficiency the heat exchange is significantly increased.

Another object of the present invention is to provide a heat exchange device for controlling water temperature, wherein the main body is made of low thermal conductivity coefficient material such as metal, plastic, glass fiber or composite material, whereby the water in the main body is not easily affected by the ambient temperature leaves, so that corrosion of the main body is avoided. Therefore, the life is prolonged and the working efficiency of the thermoelectric cooler is increased. Since an influence of the main body on the ambient temperature is avoided and the working efficiency of the thermoelectric cooler is increased, the highest performance can be reduced, so that the Costs are lower and a power saving can be achieved.

BRIEF DESCRIPTION OF THE DRAWINGS

1 an exploded view of the preferred embodiment of the invention,

2 a partial sectional view of the invention,

3 a perspective view of the main body of the invention, wherein the main body has on both sides in each case a piece of pipe and in the interior partition plates,

4 a perspective view of the main body of the invention, wherein the main body has on one side two pipe sections and in the interior partition plates,

5 a sectional view of another embodiment of the invention, wherein the main body has more than one space, each space is connected to a thermoelectric cooler and a cooling unit,

6 an exploded view of yet another embodiment of the invention,

7 a partial sectional view of yet another embodiment of the invention,

8th a sectional view of yet another embodiment of the invention, wherein the water frame has more than one space, wherein each space is connected to a thermoelectric cooler and a cooling unit.

DETAILED DESCRIPTION OF THE PREFERRED EMBODIMENT

Like from the 1 and 2 can be seen, the heat exchange device according to the invention for controlling the water temperature, in particular for use on aquarium and suitable for seawater system comprises a main body ( 1 ), which is made of material with a low coefficient of thermal conductivity, a thermoelectric cooler ( 2 ) and a cooling unit ( 3 ). The main body ( 1 ) has a room ( 11 ) for water and on the same side or on both sides two pieces of tubing ( 12 ) for water inlet and a water outlet. One side of the main body ( 1 ) is open. The open side of the main body ( 1 ) is with the heat receiving surface ( 21 ) of the thermoelectric cooler ( 2 ) connected. The cooling unit ( 3 ) is with the heat transfer surface ( 21 ) connected. The cooling unit ( 3 ) includes a heat conducting element ( 31 ) and an air cooling element ( 32 ). The pump ( 4 ) conveys the water (A) through a hose ( 41 ), with a piece of pipe ( 12 ) of the main body ( 1 ), in the room ( 11 ) of the main body ( 1 ). The water (A) in the main body ( 1 ) stands directly with the heat receiving surface ( 21 ) of the thermoelectric cooler ( 2 ), whereby the temperature of the water (A) from the heat receiving surface ( 21 ) of the thermoelectric cooler ( 2 ) is reduced. The heat of the heat transfer surface ( 22 ) is transferred to the cooling unit ( 3 ), which carries out a heat exchange with the air. The main body ( 1 ) is made of low thermal conductivity material such as metal, plastic, glass fiber or composite material. This allows the water (A) in the main body ( 1 ) are not easily influenced by the ambient temperature, so that corrosion of the main body ( 1 ) is avoided. Therefore, the life is prolonged and the working efficiency of the thermoelectric cooler ( 2 ) elevated. Since an influence of the main body ( 1 ) is avoided by the ambient temperature and the working efficiency of the thermoelectric cooler ( 2 ), the highest performance can be reduced, so that the costs are lower. Through a control computer ( 5 ), the water temperature, the thermoelectric cooler ( 2 ) and the cooling unit ( 3 ) be monitored. If the temperature of the water (A) is higher than a preset temperature, the control computer can adjust the speed of the pump ( 4 ) adjust the heat output of the thermoelectric cooler ( 2 ) and the air cooling element ( 32 ) of the cooling unit ( 3 ) to heat the heat conducting element ( 31 ) to cool. As a result, the temperature of the water (A) can be controlled quickly, so that a power saving is achieved. The cooling unit ( 3 ) may be a water cooling unit or an air cooling unit. In the present embodiment, the cooling unit ( 3 ) an air cooling unit.

How out 3 can be seen, the main body ( 1 ) at the two sides in each case a piece of pipe ( 12 ) for the water (A). In the room ( 11 ) of the main body ( 1 ) is at least one partition plate ( 111 ) is provided so that a meandering channel for the water can be formed.

How out 4 can be seen, the main body ( 1 ) on the same side two pieces of pipe ( 12 ) for the water (A). In the room ( 11 ) of the main body ( 1 ) is at least one partition plate ( 111 ) is provided so that a meandering channel for the water is formed.

The main body ( 1 ) and the thermoelectric cooler ( 2 ) can be replaced by a mounting frame ( 23 ). The main body ( 1 ) and the mounting frame ( 23 ) have screw holes ( 13 ) 231 ). The screws ( 131 ) fasten the main body ( 1 ) and the mounting frame ( 23 ), whereby the main body ( 1 ) with the thermoelectric cooler ( 2 ) connected is. Between the main body ( 1 ) and the thermoelectric cooler ( 2 ) is a waterproof ring ( 14 ) intended.

5 shows a further embodiment of the invention, wherein the main body ( 1 ) more than one room ( 11 ) having. Every room ( 11 ) has a channel ( 15 ) for the water (A). Every room ( 11 ) is equipped with a thermoelectric cooler ( 2 ) connected. Each thermoelectric cooler ( 2 ) is at the heat transfer surface ( 22 ) with a cooling unit ( 3 ) connected. This puts the water ( 1 ) in the room ( 11 ) of the main body ( 1 ) directly with the heat receiving surface ( 21 ) at least one thermoelectric cooler ( 2 ) in contact, so that the temperature of the water (A) directly through the heat receiving surface ( 21 ) of the thermoelectric I cooler ( 2 ) is reduced.

6 and 7 show yet another embodiment of the invention, which includes a water frame ( 6 ) of low thermal conductivity coefficient material, a set of thermoelectric coolers ( 2 ) and a set of cooling units ( 3 ). The water frame ( 6 ) forms a space ( 61 ) for the water. The water frame ( 6 ) has on the same side or on the two sides two pieces of tubing ( 62 ) on. The heat absorption surfaces ( 21 ) of the thermoelectric cooler ( 2 ) are with the top and the bottom of the water frame ( 6 ) connected. At the heat release sides ( 22 ) of the thermoelectric cooler ( 2 ) is a cooling unit ( 3 ) arranged. The cooling unit ( 3 ) includes a heat conducting element ( 31 ) and an air cooling element ( 32 ). The pump ( 4 ) conveys the water (A) through a hose ( 41 ), with a piece of pipe ( 62 ) of the water frame ( 6 ), in the room ( 61 ) of the water frame ( 6 ). The water (A) in the water frame ( 6 ) stands directly with the heat receiving surfaces ( 21 ) of the thermoelectric cooler ( 2 ), whereby the temperature of the water (A) of the heat receiving surfaces ( 21 ) of the thermoelectric cooler ( 2 ) is reduced. The heat of the heat receiving surfaces ( 22 ) is applied to the cooling units ( 3 ), which carry out a heat exchange with the air. The water frame ( 6 ) is made of low thermal conductivity material such as metal, plastic, glass fiber or composite material. This allows the water (A) in the water frame ( 6 ) not easily influenced by the ambient temperature. Through a control computer ( 5 ), the water temperature, the thermoelectric cooler ( 2 ) and the cooling units ( 3 ) be monitored. The temperature of the water (A) can be controlled quickly, so that a power saving is achieved.

The water frame ( 6 ) and the thermoelectric coolers ( 2 ) can each be replaced by a mounting frame ( 23 ). The water frame ( 6 ) and the mounting frames ( 23 ) have screw holes ( 63 ) 231 ). The screws ( 231 ) attach the water frame ( 6 ) and the mounting frames ( 23 ), whereby the water frame ( 6 ) with the thermoelectric coolers ( 2 ) connected is. Between the water frame ( 6 ) and the thermoelectric coolers ( 2 ) is a waterproof ring ( 64 ) intended.

8th shows yet another embodiment of the invention, wherein the water frame ( 6 ) more than one room ( 61 ) having. Every room ( 61 ) has a channel ( 65 ) for the water (A). Every room ( 61 ) is on the two sides each with a thermoelectric cooler ( 2 ) connected. Each thermoelectric cooler ( 2 ) is at the heat transfer surface ( 22 ) with a cooling unit ( 3 ) connected. This puts the water ( 1 ) in every room ( 61 ) of the water frame ( 6 ) directly with the heat receiving surface ( 21 ) at least one thermoelectric cooler ( 2 ) in contact, so that the temperature of the water (A) directly through the heat receiving surfaces ( 21 ) of the thermoelectric cooler ( 2 ) is reduced.

The thermoelectric cooler ( 2 ) can be replaced by a heat source, such as central unit. The open side of the main body ( 1 ) is connected to the heat source, whereby a water cooling system with a high efficiency is obtained.

Therefore, the water temperature can be controlled quickly, so that a power saving is achieved.

Claims (10)

Heat exchange device for controlling the water temperature, comprising a main body ( 1 ), a thermoelectric cooler ( 2 ) and a cooling unit ( 3 ), wherein one side of the main body ( 1 ) is open, wherein the main body ( 1 ) on the open side at least one room ( 11 ) through which the water (A) flows, wherein at the space ( 11 ) of the main body ( 1 ) the thermoelectric cooler ( 2 ), whereby the space ( 11 ) of the main body ( 1 ) with the heat receiving surface ( 21 ) of the thermoelectric cooler ( 2 ), wherein the cooling unit ( 3 ) with the heat transfer surface ( 22 ), the main body ( 1 ) on the same side or on the two sides two pieces of tubing ( 12 ) for water inlet and a water outlet, wherein a pump ( 4 ) the water (A) through a piece of pipe ( 12 ) of the main body ( 1 ) in the room ( 11 ) of the main body ( 1 ), the water (A) in the main body ( 1 ) directly with the heat receiving surface ( 21 ) of the thermoelectric Cooler ( 2 ), whereby the temperature of the water (A) from the heat receiving surface ( 21 ) of the thermoelectric cooler ( 2 ) is reduced, the heat of the heat transfer surface ( 22 ) of the thermoelectric cooler ( 2 ) to the cooling unit ( 3 ), which conducts heat exchange with the air. Heat exchange device according to claim 1, characterized in that the main body ( 1 ) more than one room ( 11 ), each room ( 11 ) a channel ( 15 ) for the water (A), each space ( 11 ) with a thermoelectric cooler ( 2 ), each thermoelectric cooler ( 2 ) at the heat delivery surface ( 22 ) with a cooling unit ( 3 ), whereby the water ( 1 ) in the room ( 11 ) of the main body ( 1 ) directly with the heat receiving surface ( 21 ) at least one thermoelectric cooler ( 2 ) is in contact, so that the temperature of the water (A) directly through the heat receiving surface ( 21 ) of the thermoelectric cooler ( 2 ) is reduced, the heat of the heat transfer surface ( 22 ) of the thermoelectric cooler ( 2 ) to the cooling unit ( 3 ), which conducts heat exchange with the air. Heat exchange device according to claim 1, characterized in that the main body ( 1 ) is made of low thermal conductivity coefficient material, such as metal, plastic, glass fiber or composite material. Heat exchange device according to claim 1, characterized in that by a control computer ( 5 ) the water temperature, the thermoelectric cooler ( 2 ) and the cooling unit ( 3 ), whereby the temperature of the water (A) can be quickly controlled, so that a power saving is achieved. Heat exchange device according to claim 1, characterized in that in space ( 11 ) of the main body ( 1 ) at least one partition plate ( 111 ) is provided so that a meandering channel is formed for the water. Heat exchange device according to claim 1, characterized by a fixing frame ( 23 ), the main body ( 1 ) and the mounting frame ( 23 ) Screw holes ( 13 . 231 ), the screws ( 131 ) the main body ( 1 ) and the mounting frame ( 23 ), whereby the main body ( 1 ) with the thermoelectric cooler ( 2 ) connected is. Heat exchange device for controlling the water temperature, which is a water frame ( 6 ), a set of thermoelectric coolers ( 2 ) and a set of cooling units ( 3 ), the water frame ( 6 ) a room ( 61 ) for the water (A), the water frame ( 6 ) on the same side or on the two sides two pieces of tubing ( 62 ), where on both sides of the room ( 61 ) of the water frame ( 6 ) in each case a thermoelectric cooler ( 2 ), wherein the heat absorption surfaces ( 21 ) of the thermoelectric cooler ( 2 ) with the top and the bottom of the water frame ( 6 ) are connected, wherein at the heat delivery sides ( 22 ) of the thermoelectric cooler ( 2 ) each a cooling unit ( 3 ) is arranged, wherein a pump ( 4 ) the water (A) through a piece of pipe ( 62 ) of the water frame ( 6 ) in the room ( 61 ) of the water frame ( 6 ), whereby the water (A) in the water frame ( 6 ) directly with the heat receiving surfaces ( 21 ) of the thermoelectric cooler ( 2 ), whereby the temperature of the water (A) of the heat receiving surfaces ( 21 ) of the thermoelectric cooler ( 2 ), whereby the heat of the heat receiving surfaces ( 22 ) of the thermoelectric cooler ( 2 ) on the cooling units ( 3 ), which carry out a heat exchange with the air. Heat exchange device according to claim 7, characterized in that the water frame ( 6 ) more than one room ( 61 ), each room ( 61 ) a channel ( 65 ) for the water (A), each space ( 61 ) on both sides each with a thermoelectric cooler ( 2 ), each thermoelectric cooler ( 2 ) at the heat delivery surface ( 22 ) with a cooling unit ( 3 ), whereby the water ( 1 ) in the room ( 61 ) of the water frame ( 6 ) directly with the heat receiving surface ( 21 ) at least one thermoelectric cooler ( 2 ) is in contact, so that the temperature of the water (A) directly through the heat receiving surfaces ( 21 ) of the thermoelectric cooler ( 2 ), whereby the heat of the heat receiving surfaces ( 22 ) of the thermoelectric cooler ( 2 ) on the cooling units ( 3 ), which carry out a heat exchange with the air. Heat exchange device according to claim 7, characterized in that the water frame ( 6 ) is made of low thermal conductivity coefficient material, such as metal, plastic, glass fiber or composite material. Heat exchange device according to claim 7, characterized in that by a control computer ( 5 ) the water temperature, the thermoelectric coolers ( 2 ) and the cooling units ( 3 ), whereby the temperature of the water (A) can be quickly controlled, so that a power saving is achieved.

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