RU75020U1 - DEVICE FOR COOLING THE HEATING EQUIPMENT - Google Patents

Abstract

1. A device for cooling heat-generating equipment, comprising a radiator, a heat-receiving base, a heat transfer element such as a heat pipe in contact with a heat-receiving base and made of a housing with a wick of capillary structure, characterized in that it is equipped with a battery of multi-element thermoelectric generators located on the condenser part of the heat pipes and connected to a radiator. 2. The device according to claim 1, characterized in that between the casing of the heat pipe and the wick of the capillary structure there is an insulating high-heat-conducting layer, the casing of the condenser part of the heat-pipe is made in the form of a lattice structure, in the windows of which there are thermoelectric generators forming a battery and bonded to an insulating high-heat-conducting layer. 3. The device according to claim 1 or 2, characterized in that the heat pipe is made in the form of a flat panel. The device according to claim 1 or 2, characterized in that the heat pipe is made rectangular. The device according to claim 1 or 2, characterized in that the heat pipe is made coaxial. The device according to claim 1 or 2, characterized in that the radiator is plate-shaped. The device according to claim 1 or 2, characterized in that the radiator is made needle-shaped. The device according to claim 1 or 2, characterized in that the battery of multi-element thermoelectric generators is formed by cascade elements. The device according to claim 1 or 2, characterized in that the thermocouples of the battery of thermoelectric generators are made of polymeric materials. The device according to claim 1 or 2, characterized in that the thermocouples of the battery of thermoelectric generators are manufactured�

Description

The invention relates to heat exchangers based on heat pipes, which can be used to cool electronic devices, electrical and other heat generating units, and also relates to the technique of heat exchangers used to cool heat generating equipment.

A device based on a heat pipe is known for cooling electronic equipment (Alekseev V.A., Arefyev V.A. Heat pipes for cooling and thermostating electronic equipment. M: Energy 1979., Figure 43, page 93), containing a flat thermal a pipe, on the condenser part of which finned radiators are installed, tightened by screws. Fuel elements are glued to a radiator-free surface on one or both sides.

The main disadvantages of this device are the insufficient reliability of the fastening of the fuel elements to the surface of the heat pipe, as well as the fact that all the heat removed from the fuel elements is discharged into the surrounding space, although some of this heat can be used.

A device is known for cooling a crystal of a computer processor (application for US patent No. 2001/0001981, published on May 31, 2001, FIGS. 4 and 13), comprising a radiator made in the form of a set of horizontally located heat-conducting fins strung on a heat transfer element made in the form of one or more U-or V-shaped heat pipes of circular cross section, vertically mounted on a horizontal heat-receiving base,

a directing air duct located horizontally, an axial fan mounted on a radiator, the longitudinal axis of which is located horizontally. The axis of rotation of the fan is located on the longitudinal axis of the radiator and is parallel to the plane of the heat-receiving base. Heat pipes have thermal contact with their lower curved part with a heat-receiving base, on which the processor chip is mounted. The lateral branches of the heat pipes directed upward contact with their surface with those parts of the radiator fins that are inside the radiator in its middle part, that is, in the zone located between its perimeter and its horizontally located longitudinal axis. The radiator, composed of a vertical row of horizontally spaced ribs, has a rectangular perimeter located around its longitudinal geometric axis.

This device has a number of disadvantages: to intensify the cooling process, the radiator is blown with air, which is supplied using an axial fan, the drive of which consumes electric energy; all heat removed from the processor is discharged into the surrounding space, although part of this heat can be disposed of.

A device is known (patent RU 2263371, H01L 23/34, publ. October 27, 2005 - prototype) used to cool a crystal of a computer processor, comprising a radiator with fins, a heat transferring base and a heat transfer element such as a heat pipe having heat contact with a heat transferring base and with fins of the heatsink, an axial fan located on the longitudinal axis of the heatsink, crystal processor. The perimeter of the radiator, formed by the outer sides of its ribs with respect to the longitudinal axis of the radiator, has a circle shape, and the heat transfer element is mounted on the radiator along its perimeter, while the radiator fins are located radially with respect to its longitudinal axis.

This device has several disadvantages: the complexity of the design of the device, to intensify the cooling process, the radiator is blown with air, which is supplied using an axial fan, to the drive of which electric energy is consumed; the heat removed from the electronic device is discharged into the environment, although part of this heat can be used to produce electrical energy.

The proposed solution is based on a technical problem, which consists in eliminating the above-mentioned drawbacks, namely, reducing the energy costs of cooling, using the heat removed to produce electricity and simplifying the design.

The stated technical problem is solved in that a device for cooling heat-generating equipment, comprising a radiator, a heat-receiving base, a heat transfer element such as a heat pipe in contact with a heat-receiving base and made of a housing with a wick capillary structure, according to the proposal, is equipped with a battery of multi-element thermoelectric generators located on the condenser part of the heat pipe and connected to the radiator.

Another feature of the device is that between the casing of the heat pipe and the wick of the capillary structure there is an insulating high-heat-conducting layer, the casing of the condenser part of the heat-pipe is made in the form of a lattice structure, in the windows of which there are thermoelectric generators forming a battery and bonded to an insulating high-heat-conducting layer.

In addition, the heat pipe can be made in the form of a flat panel, rectangular or coaxial, and the radiator is made of plate or needle.

The battery of multi-element thermoelectric generators can be formed by cascade elements, and battery thermoelements

thermoelectric generators are made of polymer or nanostructured materials.

The technical result of the proposed utility model is expressed in simplifying the design of the heat sink unit, the exclusion from the cooling system of consumers of electric energy, for example, a fan. The developed device allows you to use part of the heat removed to produce electrical energy.

Simplification of the design of the heat sink unit is achieved by the fact that the heat transfer element - the heat pipe is made, for example, in the form of a flat panel, thereby increasing the useful contact area of the heat pipe with the heat receiving base. This also allows the use of simplified methods for installing elements on a heat pipe.

An exception to the cooling system of consumers of electrical energy is achieved by the fact that part of the heat removed is converted into electrical energy in a battery of thermoelectric generators, and radiators cooled by free air convection are used to dissipate the remaining heat. Also, this effect is achieved through the use of a developed heat transfer surface provided by the design of the radiator.

The use of part of the heat removed from the heat-generating equipment for the production of electrical energy is achieved by the fact that a new element is introduced into the device - a battery of thermoelectric generators that convert the heat passing through them into electrical energy due to the Seebeck effect. The resulting electrical energy can be used in the energy supply system of the fuel equipment.

The technical result achieved can be enhanced if an insulating high-heat-conducting layer is placed between the casing of the heat pipe and the wick of the capillary structure, the casing of the condenser part of the heat pipe is made in the form of a lattice structure, in the windows

which sets thermoelectric generators that form a battery and are bonded to an electrically insulating high-conductive layer. Due to the use of this design, the mass of the device is reduced, since the battery of thermoelectric generators partially performs the function of the supporting structure of the casing of the condenser part of the heat pipe and the mass of the casing is reduced due to the use of a lattice structure without reducing the strength of the casing. The use of this design provides a reduction in thermal resistances between the heat-generating equipment and the battery of thermoelectric generators, reduces leakage of thermal energy not used for the production of electric energy, and this, in turn, provides an increase in the efficiency of thermoelectric generators.

To increase the efficiency of using the contact surface of the heat-receiving base with the heat pipe and increase the efficiency of using the space surrounding the device, the following forms of the heat pipe can be used: rectangular and coaxial.

To increase the heat removal from the radiator, the radiator grill can be made lamellar or needle.

To increase the efficiency of the battery of thermoelectric generators, thermocouples can be cascaded.

To reduce the cost of a battery of thermoelectric generators, thermoelements can be made of polymeric materials.

To increase the efficiency of the battery of thermoelectric generators, thermoelements can be made of nanostructured materials.

The essence of the proposed utility model is illustrated by drawings, where Fig. 1 schematically shows a device for cooling heat-generating equipment, in which a battery of thermoelectric generators is connected to the condenser part of the heat pipe in the form of a detachable connection; on

figure 2 is a side view of the device of figure 1; figure 3 is a top view of a device in which the casing of the condenser part of the heat pipe is formed by a battery of thermoelectric generators; figure 4 is a view along aa on the device of figure 3; figure 5 presents a top view of a device in which the casing of the heat pipe is made rectangular, and the radiator is made of a needle; figure 6 shows the same device in which the heat pipe body is made coaxial, and the radiator is made of plate; Fig.7 is a view along BB on the device of Fig.6.

The device for cooling the heat-generating equipment, shown in figure 1, contains a heat-receiving base 1, a heat transfer element of the type heat pipe 2 having thermal contact in the evaporation zone with a heat-receiving base 1. The heat pipe 2 is made in the form of a flat panel. On the condenser part of the heat pipe 2, a battery of thermoelectric generators 3 is installed, which has thermal contact with the radiator 4. The heat-generating equipment 5 is installed on the heat-receiving base 1. Inside the heat pipe 2 there is a wick of the capillary structure 6.

The case of the condenser part of the heat pipe 2 (Fig. 4) consists of a lattice structure 7, in the windows of which the batteries of thermoelectric generators 3 are installed, which together with the sealed electrical insulating high-heat-conducting layer 8 forms the case of the condenser part of the heat pipe.

The casing of the heat pipe 2 is made rectangular, and the radiator 4 is made needle-shaped (Fig. 5). The casing of the heat pipe 2 is made coaxial, and the radiator 4 is plate-shaped (Fig. 7).

The proposed device operates as follows. In the process, the block of heat-generating equipment 5 heats up, the generated heat is perceived by the heat-receiving base 1. Heat transfers from the heat-receiving base to the evaporating part of the heat pipe 2. The working fluid located in the evaporating part

of the heat pipe 2, evaporates and in the form of steam through the steam channel enters the condensation zone of heat pipe 2, where it condenses, transferring the heat received in the evaporation zone to the body of the condenser part of the heat pipe, then the working fluid returns to the evaporation part of the heat pipe 2 through the wick of the capillary structure 6. Heat transfers from the case to the battery of thermoelectric generators 3. The heat flow passes through the elements of thermoelectric batteries, creating a temperature difference on them, which causes the Seebeck effect eneratsiyu thermopower. Received electric energy enters the payload, which can also be used in the operation of the heat-generating equipment 5. The spent thermal energy is supplied to the cooling radiator 4 and then transferred to the surrounding space.

The case of the condenser part of the heat pipe 2 having a lattice structure 7 (Fig. 4) plays the role of a supporting structure, and the windows formed by the lattice structure 7 are used to install thermoelectric battery generators. The electrically insulating high-heat-conducting layer 8 picks up the heat released during condensation of the working fluid in the condenser part of the heat pipe 2 and transfers it to thermoelectric battery generators.

Industrial applicability.

The proposed device can be used to cool devices that require intensive cooling and for which an important role is played by the reliability of the provided cooling and the saving of electrical energy consumed for this. The device can be used to cool structures for which energy saving plays an important role, since this device allows you to connect an additional energy source operating on the heat generated by the equipment to the equipment’s power supply system. The device can be used to cool electronic equipment, semiconductor devices, communications.

Claims (10)

1. A device for cooling heat-generating equipment, comprising a radiator, a heat-receiving base, a heat transfer element such as a heat pipe in contact with a heat-receiving base and made of a housing with a wick of capillary structure, characterized in that it is equipped with a battery of multi-element thermoelectric generators located on the condenser part of the heat pipes and connected to a radiator. 2. The device according to claim 1, characterized in that between the casing of the heat pipe and the wick of the capillary structure there is an insulating high-heat-conducting layer, the casing of the condenser part of the heat pipe is made in the form of a lattice structure, in the windows of which there are thermoelectric generators forming a battery and bonded to an insulating high-heat conducting layer. 3. The device according to claim 1 or 2, characterized in that the heat pipe is made in the form of a flat panel. 4. The device according to claim 1 or 2, characterized in that the heat pipe is made rectangular. 5. The device according to claim 1 or 2, characterized in that the heat pipe is made coaxial. 6. The device according to claim 1 or 2, characterized in that the radiator is made of plate. 7. The device according to claim 1 or 2, characterized in that the radiator is made needle-shaped. 8. The device according to claim 1 or 2, characterized in that the battery of multi-element thermoelectric generators is formed by cascade elements. 9. The device according to claim 1 or 2, characterized in that the thermocouples of the battery of thermoelectric generators are made of polymeric materials. 10. The device according to claim 1 or 2, characterized in that the thermocouples of the battery of thermoelectric generators are made of nanostructured materials.