DE102008016639A1 - Thermal storage tank - Google Patents

Abstract

A heat storage tank 10 includes a plastic container 11 for storing engine cooling water, an inflow pipe 30 and an outflow pipe 31 communicating with the interior of the plastic container 11 and adapted to protrude from the plastic container 11, and a heat insulating layer 13 covering the entire circumference the plastic container 11 is arranged to isolate the heat of the engine cooling water in the plastic container 11.
The heat insulating layer 13 is arranged to cover the root portions of the leads 30, 31. Therefore, the heat radiation of the engine cooling water from the bases of the pipes 30, 31 can be suppressed, whereby a reduction of the heat insulating effect can be avoided.

Description

BACKGROUND OF THE INVENTION

1. Field of the invention

These The invention relates to a heat storage tank for storage and isolating a liquid.

2. Description of the related technology

One cooling system to support of warming up a water cooled Internal combustion engine of a motor vehicle has usually been proposed in which a heat storage tank for storing and insulating the engine cooling water, which from the water-cooled Engine emanates, in the cooling water circuit is arranged and the high-temperature cooling water, which in the heat storage tank is stored in the engine is initiated to warm up the Accelerate engines. This makes it possible, the foreign or waste heat to effectively use the engine and reduce fuel consumption to reduce the overall viewing angle of the vehicle operation from.

in the Generally, the heat storage tank has a double heat insulating structure, which has an inner cylindrical tank stainless steel forming a heat storage tank body, and an outer cylindrical Tank made of stainless steel, with the space between the inner and outer cylindrical Tanks is kept substantially at vacuum.

SUMMARY OF THE INVENTION

Of the above-described heat storage tank however, requires two tanks including inner and outer cylindrical Tank, resulting in increased Costs leads.

With Looking at the above, it is the object of this invention, a Heat storage tank for Reducing costs while providing the insulation effect is maintained.

In order to achieve the above object, according to this invention, there is provided a heat storage tank comprising a tank body ( 11 ) for storing a fluid, lines ( 30 . 31 ) communicating with the interior of the tank body and protruding out of the tank body, and a heat insulating layer ( 13 ) arranged to cover the entire circumference of the tank body including the roots of the pipes and thus to isolate the heat of the fluid in the tank body.

As a result, The use of just a single tank body can Reduce costs without having two tanks, d. H. inner and outer cylindrical Tanks, to be used.

In addition, because the heat insulation layer arranged in such a way that it covers the entire circumference of the shell including the bases of the first and second lines covered, heat radiation be suppressed by the bases of the first and second lines, making it possible is, the heat insulation effect maintain.

Incidentally, represent the reference numerals, which are inserted in parentheses, which refer to the follow respective means described above, respectively the correspondence with the specific agents described in the following embodiments are used.

The The present invention may be understood from the description of preferred embodiments the invention, as they are explained below, together with the accompanying drawings more complete be understood.

BRIEF DESCRIPTION OF THE DRAWINGS

1 FIG. 15 is a diagram showing a structure of a cooling water circuit used for a heat storage tank for automobiles according to this invention.

2 shows an external appearance of the vehicle heat storage tank, which in 2 is shown.

3 FIG. 12 is a cross-sectional view showing the vehicle heat storage tank incorporated in FIG 2 is shown.

4 FIG. 15 is a perspective view showing the inside of the heat storage tank incorporated in FIG 2 is shown.

5 FIG. 15 is a diagram showing the flow of the engine cooling water in the vehicle heat storage tank, which is shown in FIG 2 is shown.

6 FIG. 15 is a diagram showing the assembling steps for the vehicle heat storage tank incorporated in FIG 2 is shown.

7 is a diagram showing the training of in 6 illustrated film layer explained.

8th is a diagram showing the training of in 6 illustrated film layer explained.

9 is a diagram showing the training of in 6 illustrated film layer explained.

10 is a diagram showing the training of in 6 illustrated film layer explained.

11 is a diagram showing the training of in 6 illustrated film layer explained.

12 is a diagram showing the training of in 6 illustrated film layer explained.

DESCRIPTION OF PREFERRED EMBODIMENTS

1 shows a structure of the cooling water circuit, which uses the heat storage tank according to an embodiment of the invention.

The cooling water circuit contains a heat storage tank 10 , a four-way valve 20 , a heating core 30 and an electrically operated pump 40 , The heat storage tank 10 serves to isolate and store the engine cooling water. The four-way valve 20 connects the exhaust side of one of cylinder head 50 and cylinder block 51 of the engine at the inlet side of at least one of heater core 30 and heat storage tank 10 ,

The heating core 30 , which forms a vehicle air conditioning system, is a heat exchanger for heating the air with the engine cooling water. The electrically operated pump 40 is a circulation pump for supplying the engine cooling water to the intake side of each cylinder head 50 and cylinder block 51 ,

In the cooling water circuit, a connection only becomes between the outlet side of the cylinder block 51 and the inlet side of the heat storage tank 10 through the four-way valve 20 causes while the temperature of the cooling water is low. As a result, this can be done in the heat storage tank 10 stored cooling water in the cylinder block 51 are fed, causing the warming up of the cylinder block 51 is accelerated.

In the process, the inlet side of the heater core 30 through the four-way valve 20 completed, and therefore, the cooling water flows out of the heat storage tank 10 only in the cylinder block 51 , Thus, the warming up of the cylinder block 51 be supported effectively.

On a subsequent increase in temperature of the cooling water to a medium level closes the four-way valve 20 the connection between the outlet side of the cylinder block 51 and the inlet side of the heat storage tank 10 while at the same time the exhaust side of the cylinder head 50 and the inlet side of the heater core 30 combines.

In the process, the engine cooling water (hot water) in the cylinder block 51 held and therefore the warm-up of the engine is accelerated. Furthermore, this is through the cylinder head 50 heated engine cooling water between the cylinder head 50 and the heater core 30 circulates, and therefore the air can pass through the heater core 30 to be heated.

In the subsequent increase in water temperature to a high level connects the four-way valve 20 the outlet side of the cylinder head 50 with the inlet side of the heater core 30 and the inlet side of the heat storage tank 10 , Then the engine cooling water flows into the heat storage tank 10 and therefore, the engine cooling water (hot water) for the next warm-up in the heat storage tank 10 stored or stored.

The structure of the heat storage tank 10 will be explained. 2 shows the appearance of the heat storage tank 10 , and 3 is a cross-sectional view taken in the plane A in FIG 2 taken.

The heat storage tank 10 is how in 2 is shown cube-shaped and has a Einstromleitung 30 and a discharge line 31 which protrudes outward from the lower part of the side wall thereof. In particular, the heat storage tank contains 10 , as in 3 is shown a plastic container (tank body) 11 and a heat insulating element 15 covering the entire outer circumference of the container 11 encloses. The thermal insulation element 15 contains both the exterior of the shell 11 , formed as a polyhedron, and at the same time the base portions of the inflow 30 and the discharge line 31 , The thermal insulation element 15 contains a plating layer 12 forming an inner air blocking layer, a heat insulating layer 13 and a film layer 14 which forms an outer air blocking layer.

The plastic container 11 has a cube-shaped structure by combining first and second partition housings. The plastic container 11 is at the inflow line 30 and the discharge line 31 connected, which are connected to the interior of the same. The inflow line 30 and the discharge line 31 are made of a synthetic resin or made of synthetic resin.

The plastic container 11 and the wires 30 . 31 are formed of a synthetic resin material such as PPS, PPA or NY66 mixed with glass fiber. The plastic container 11 and the wires 30 . 31 are formed of an element which the di from 1 mm to 5 mm.

The plating layer 12 is a thin metal coating (made of, for example, aluminum) formed by the plating method in such a manner as to be the outer surface of the plastic container 11 covered. The thermal insulation layer 13 is designed to the entire outer surface of the plastic container 11 including the bases of the inflow line 30 and the discharge line 31 to cover. The thermal insulation layer 13 is formed of glass wool, mineral wool, urethane foam or polystyrene and the like. The thermal insulation layer 13 has the thermal conductivity of not more than 0.01 (kcal / hm ° C). The film layer 14 is formed of a laminate film and encloses the whole of the heat insulating layer 13 , The film layer 14 and the plating layer 12 are designed to prevent the transmission of air.

The plating layer 12 covers the entire outer surface of the shell 11 and the bases of the inflow line 30 and the discharge line 31 , As a result, the edges of the plating layer are 12 only as two annular edges around the outer circumference of the inflow line 30 and the outer periphery of the discharge line 31 exposed around. On the other hand, the film layer 14 formed in the shape of a cylinder or a bag by folding a flat film molding and gluing of its edges together. The film layer 14 has two annular edges around the circumference of the inflow line 30 and the circumference of the discharge line 31 on. The plating layer 12 and the film layer 14 are at two points around the inflow line 30 and the circumference of the discharge line 31 glued or welded. This structure is effective for suppressing heat transfer from the plating layer 12 on the film layer 14 , connections 21 . 23 between the plating layer 12 and the film layer 14 are referred to as first ports while ports 20 . 22 between the film layers 14 be referred to as second ports.

4 and 5 show the internal structure of the heat storage tank 10 , Several subdivision plates 40 are parallel to each other in the vertical direction in the heat storage tank 10 arranged. Each space between the several partition plates 40 forms a parallel flow path 41 , The parallel flow paths 41 serve to supply the engine cooling water in the vertical direction.

The several partition plates 40 are offset vertically in alternating staggered fashion, and are passed through the floor surface or the ceiling of the heat storage tank 10 carried.

reverse paths 42 . 43 for reversing the flow of the engine cooling water are in the upper or lower side of the plurality of partition plates 40 educated. The reversal paths 42 . 43 are arranged alternately in the direction in which the partition plates 40 are arranged. The reversal paths 42 sweep the upward flow down. The reversal paths 43 reverse the downward flow.

The several partition plates 40 are made of a synthetic resin material integral with the plastic container 11 and the wires 30 . 31 educated. The several partition plates 40 are formed with a thickness of 1 mm to 2 mm.

In this structure, the engine cooling water flows in the plurality of parallel paths 41 and the several reversal paths 42 and 43 , The engine cooling water thus flows zigzag, as indicated by arrows in 5 is shown. Consequently, the engine cooling water coming out of the inflow line 30 flows in, from the discharge line 31 flow out, without mixing with the engine cooling water, which previously inside the heat storage tank 10 present.

A method of manufacturing a heat storage tank 10 according to this embodiment will be explained.

6 is a diagram showing the assembly steps, and 7 and 8th Figures are diagrams showing the steps for forming the film layer 14 demonstrate.

First, a plastic container 11 as in (a) of 6 by combining the first and second partition housings 11a . 11b educated.

Next, a thin metal coating is formed as in (b) of FIG 6 is shown by the entire outer surface of the plastic container 11 is plated.

In the method, the thin metal coating is formed in such a manner that these respective root portions of the leads 30 . 31 cover. Thus, the plating layer becomes 12 educated.

Then the thermal insulation layer becomes 13 on the exterior of the plating layer 12 educated. In particular, glass wool (ie, heat insulating material) is disposed in such a manner that the entire outer surface of the plastic container 11 including the root sections of pipes 30 . 31 be covered as in (c) of 6 is shown.

Next is the film layer 14 , as in (d) of 6 is shown on the outside of the thermal insulation layer 13 educated.

In particular, as in 7 is shown, a rectangular laminate film 14a prepared, and folded back in channel form, as in 8th is shown.

Then, as in 9 is shown, two end sections 14b . 14c of the laminate film 14a heat sealed or welded together. The result is a laminate film 14a formed in the shape of a rectangular tube.

Then, as in 10 shown is circular holes 140 . 141 in the upper parts of the two opposite side walls of the laminate film 14a formed in the shape of a rectangular tube.

Then become circular holes 140 . 141 extruded through the heat pressing process, creating cylindrical sections 140a . 141 be trained as in 11 is shown.

Next, upper end portions 142 . 143 of the laminate film 14a folded in the form of a rectangular tube in an overlapping shape and heat sealed or welded together. As a result, a heat-sealing portion becomes 22 ( 3 ) at the upper end of the laminate film 14a educated. The heat seal section 22 represents a part in which upper end portions 142 . 143 be attached by heat seal close or close to each other.

The laminate film 14a is formed in the shape of a rectangular tube, and upper end portions 142 . 143 they are hermetically closed. Subsequently, the plastic container 11 with the plating layer 12 and the thermal insulation layer 13 in the laminate film 14a used in the form of a rectangular tube, as described above.

Then the lines 30 . 31 each in cylindrical sections 140a . 141 used. As a result, a first gap between the cylindrical portion 140a and the line 30 , and a second gap between the cylindrical portion 141 and the line 31 generated.

Lower end sections 144 . 145 of the laminate film 14a in the form of a rectangular tube are folded in an overlapped form and heat-sealed or welded together ((d) in FIG 6 ). As a result, a heat-sealing portion becomes 20 ( 3 ) at the lower part of the laminate film 14a educated. The heat seal section 20 represents a part in which lower end portions 144 . 145 heat sealed to each other.

Then, vacuum is introduced from the above-described first and second columns. In addition, the cylindrical section 140a of the laminate film 14a the line 30 to the plating layer 12 heat sealed or welded. In the line 31 becomes the cylindrical section 141 of the laminate film 14a at the plating layer 12 heat sealed or welded.

As a result, heat seal portions 21 . 23 ( 3 ) on the laminate film 14a educated. The heat seal section 21 represents a part in which the cylindrical section 140a ( 12 ) of the laminate film 14a to the plating layer 12 on the outer surface of the pipe 30 is heat sealed or welded. The heat seal section 23 represents a part in which the cylindrical section 141 ( 12 ) of the laminate film 14a at the plating layer 12 on the outside surface of the pipe 31 is heat sealed. Thus, space becomes between the plating layer 12 and the laminate film 14a formed essentially in a vacuum.

According to the above-described embodiments, the storage tank includes 10 a plastic container 11 for storing the engine cooling water, a inflow line (first line) 30 and a discharge pipe (second pipe) 31 which are connected to the interior of the plastic container 11 are communicatively connected, and formed in such a way that they from the plastic container 11 stick out, and a heat insulation layer 13 To cover the entire circumference of the plastic container 11 and for isolating the engine cooling water in the plastic container 11 is arranged, wherein the heat insulating layer 13 for covering also the root sections of lines 30 . 31 are arranged.

Thus, heat of engine cooling water is prevented from leaking from the bases of conduits 30 . 31 is emitted. Only one plastic container (tank body) 11 is used but not two tanks, including inner and outer cylindrical tanks, which reduces costs. Therefore, the cost can be reduced while maintaining the insulating effect.

Other Embodiments

The above-described embodiments constitute a case in which a thin metal coating is used as a plating layer 12 on the outer surface of the plastic container 11 is trained. As an alternative to the plating layer 12 For example, a thin film made of a synthetic resin material may be used. which can close the air. The film material may be formed to the outside of the plastic container 11 instead of the plating layer 12 to cover. In this case, the inner film layer covering the plating layer covers 12 replaced, the entire tank body 11 and is formed in such a manner that an edge suitable for bonding with the outer film layer only around the leads 30 . 31 is arranged.

The above-described embodiments illustrate a case in which the space between the plating layer 12 and the film layer 14 is formed in a vacuum to improve the thermal insulation characteristic. Nevertheless, the room can be formed without vacuum.

The embodiments described above represent a case in which the plastic container 11 is used as a tank body. Alternatively, a metal tank may be used as a tank body.

The embodiments described above represent a case in which an inflow line 30 and a discharge line 31 are formed in such a way that they outwardly at the lower part of the side wall of the plastic container 11 protrude. However, the invention is not limited to this structure, but the inflow line 30 and the discharge line 31 can at any point of the plastic container 11 to be ordered. Also, instead of building in which two wires 30 . 31 independently of each other in spaced relation to each other, a structure in which lines are applied 30 . 31 are adjacent to each other, or provided as a single double line.

The Embodiments described above illustrate a case in which the engine cooling water is used as the fluid becomes. Alternatively you can other fluids like the oil be used.

The embodiments described above represent a case in which the heat storage tank 10 mounted on the vehicle. Alternatively, the heat storage tank 10 be used with any of a variety of facilities, such as a container for insulating the hot bath water.

While the Invention have been described with reference to specific embodiments, which for Purposes of illustration, it should be apparent that that varied modifications to be carried out by those skilled in the art can, without departing from the basic concept and scope of the invention departing.

Claims (8)

Thermal storage tank, full: a tank body for storing a fluid; Lines connected to the interior communicating the tank body are connected, and formed from the tank body outstanding are; and a thermal insulation layer, to cover the entire circumference of the tank body including the Root sections of the lines and thus to isolate the heat of Fluids in the tank body are arranged. Thermal storage tank according to claim 1, the tank body is formed of a synthetic resin material, being an inner one Air blocking layer on the outer surface of the tank body to Preventing the passage of air is formed, wherein the heat insulating layer on the exterior of the inner air blocking layer is arranged, wherein an outer air blocking layer is arranged to cover the heat insulating layer for preventing of the air passage, and wherein the inner and outer air blocking layers are coupled to each other by edges of it, and the space between the inner and outer air blocking layer hermetically sealed. Thermal storage tank according to claim 2, with connectors for coupling the inner air blocking layer and the outer air blocking layer on each other on the outer circumference the lines are arranged. Thermal storage tank according to claim 3, the connections between the inner air blocking layer and the outer air blocking layer only on the outer circumference the lines are arranged. The heat storage tank according to claim 1, wherein the conduits are formed with a first conduit communicated with the interior of the tank body and in such a manner as to protrude from the tank body for supplying a fluid into the tank body, and a second conduit communicating with the interior of the tank body, and formed in such a manner as to protrude from the tank body for discharging a fluid from the tank body, and wherein the tank body includes a plurality of partition plates arranged therein such that the inflowing fluid flows out of the first conduit from the second conduit after it has zigzagged in the body of the tank has flowed. Thermal storage tank according to claim 5, wherein the lines arranged at the lower part of the tank body are. Thermal storage tank according to claim 1, wherein the heat insulating layer the thermal conductivity of not more than 0.01 (kcal / hm ° C) having. Thermal storage tank according to claim 1, wherein the fluid is the engine cooling water of the motor vehicle.