DE19839867A1 - Heat pump for buildings has ice making and storage unit using water and glycol fluid medium to separate ice sheet from evaporator plate - Google Patents

Abstract

The underground ice container (7) contains a heat pump absorber (2) on which the ice is formed and a reservoir (6) for separation fluid pumped (3) around a circuit containing the absorber, expansion valve and heat exchanger. Water is topped up from a reservoir (8).

Description

The invention relates to a water-filled storage container, the content of which is with a heat pump Energy is withdrawn until it is completely or partially frozen to ice.

With the heat removed, residential or commercial rooms can be heated in the cold season; Conversely, it is possible to cool it in summer, with a corresponding amount of heat being supplied to the ice depot in order to melt it again into liquid water, whereupon its heat potential is again available for heating purposes. This makes it possible to use the electrical energy that was used to operate the heat pump, so to speak, a second time for cooling purposes, or, viewed the other way round, the waste heat, e.g. B. a refrigerated counter for food for water heating for a hotel or a restaurant kitchen. If the summer cooling load is not sufficient to melt the entire ice stock, additional heat can be added to the ice storage with a solar collector, the efficiency of the collector is optimally supported by the low return temperatures. Another buffer storage for the "warm" side of the heat pump, preferably also a latent heat storage, but with paraffin as the storage medium, the temperature of which is around 50 ° C, enables the heat pump to be operated with cheap night-time electricity. The CO ₂ balance of the plant is u. U. Improved again, because it then gets its energy mainly from base load power plants.

The investment in the ice storage pays off very quickly, since other costs, e.g. B. for that Hitting a groundwater well, or for laying pipe coils in the ground, for There is no need to open up a heat source. In contrast to the seasonal storage of solar heat in a hot water storage tank, an ice storage tank does not have to be insulated, it is even cheaper if it is created as an earth storage and extracts additional heat from the surrounding soil in winter, or keeps the ice supply cold with this supercooled environment in summer. He can e.g. B. from prefabricated concrete rings in the form of a cistern with little economic effort become. The heat extraction with the help of a heat pump, below the phase change temperature has the advantage that, in addition to the sensitive heat of the water supply, the water too Latent heat can be removed, it corresponds approximately to the sensible heat for one Temperature rise of 80 ° K. The storage capacity doubles compared to a sensitive one Hot water storage, the use for cooling purposes is only possible in this way. However, ice formation requires a special design of the heat exchanger or Evaporator of the heat pump, since the ice layer that forms on its surface starts at one point certain thickness impedes the heat flow too much.

A possible solution to this problem is described in DE-OS 27 15 075. If the size of the heat exchanger surface is chosen so that it is perfectly even frozen water supply allows a sufficiently large heat flow, can on a cyclical Detachment of the ice layer from the heat exchanger surface can be dispensed with. However, it is hardly possible to make such a large heat exchanger economically sensible, especially in With regard to mechanical problems resulting from the change in volume of the ice.

DE-OS 30 11 840 does not solve these problems satisfactorily.

The solution proposed in US Pat. No. 5,207,075, the water in one of the Freezing point cooled, water-immiscible fluid to freeze to ice spheres Although the above problems, but the effort for this fluid z. B. for a suitable Oil flowable even at low temperatures, disproportionately high.

DE 44 05 991 describes an absorber which is arranged outside the water supply and sprayed or poured over with this.

The resulting ice layer is detached from the absorber when it reaches a certain thickness, by switching it briefly to the heat pump condenser and thus heating it up.

With this arrangement, however, it appears very difficult to spray or spray onto the absorber. Dosing the amount of water poured over it so that it completely freezes on it. Through the Formation of the ice layer changes the heat transfer constantly when the applied one Water quantity is not reduced to exactly this extent, it happens that part of the water not frozen to the absorber, but undercooled, similar to the sometimes occurring "freezing rain" in the water tank flows.  

Together with the pieces of ice already there, it can be cooled to below freezing Freeze water to a closed ice cover, which also extends to the Container wall freezes, or jams there and thus a further removal of water prevents the entire process from coming to a standstill. Another disadvantage of the arrangement described is the switchover of the absorber to the Condenser of the heat pump, since this is a mechanically quite demanding and also prone to failure Valve requires, moreover, the efficiency of the heat pump deteriorates. The arrangement of the absorber over the water surface finally wasted this part of the Storage volume.

The object of the present invention is to provide an arrangement for an ice store, which reliably solves the problems of the aforementioned proposals and also under economic Aspects can be meaningfully implemented.

For this purpose, the evaporator of the heat pump, or an absorber through which a refrigerant flows, which is cooled by the heat pump below the freezing point of water, in the lower area of the water supply attached. Because liquid water has been in this area for the longest time the ice formed on the absorber rise from there in the water reservoir as soon as it is from the surface of the absorber is detached.

To achieve this detachment easily, as well as without interrupting the heat removal, a Separating fluid, whose freezing point is below the evaporation temperature of the refrigerant of the heat pump is, e.g. B. used a water-glycol mixture to the absorber surface so far to heat up so that the adhering layer of ice comes off. This process is repeated periodically, as soon as the ice layer has reached the maximum permissible thickness. In addition, the hydraulic pressure this separation fluid can also be used to deform the surface of the absorber, or it to press against a cutting grid in order to additionally remove the ice layer from to reach the absorber surface. It has proven to be useful to heat the Separating fluid by means of a suitable heat exchanger from the lower, 4 ° C closest part of the Water supply. This removes additional heat from it, only when it does the water in this area has cooled to near freezing, it may be necessary that Heat the separation fluid with a suitable device to ensure that the entire water supply is reliable to freeze to ice, and thus make maximum use of the storage capacity.

Embodiments of the invention are explained below with reference to the drawings.

List of reference numbers

1

Concrete ring f. Storage tank

2nd

Absorber of the heat pump

3rd

Circulation pump f. Separation fluid

4th

throttle

5

Heat exchanger f. Separation fluid

6

Expansion tank

7

Ice stock

8th

Water filling the ice storage

9

Intake pipe

10th

Circulation pump

11

Distributor head

16

Evaporator body d. Heat pump

17th

,

17th

a ice cream bearer

18th

Layer of ice

19th

Cutting grid

20th

Separation fluid

20th

a static separation fluid

21

Cavity f. Separation fluid

26

compressed air

27

elastic bubble in expansion tank B1

28

elastic bladder in expansion tank B2

29

Gas filling

30th

Heat exchanger

Fig. 1 shows a storage container, which is made up of concrete rings 1 . It is filled with a water supply 8 . In its lower area there is the absorber 2 of a heat pump. A circulation pump 3 is provided which, against the flow resistance of a throttle 4 , circulates a separating fluid through the absorber 2 and through a heat exchanger 5 . An expansion vessel 6 enables a change in volume of the circulating separation fluid, whereby it is achieved that the surface of the absorber is deformed against the static pressure of the water filling 8 of the memory. This process is explained in more detail using the drawings in Fig. 2. Numbers 9 , 10 and 11 denote the cooling circuit, or its intake pipe, circulation pump and a distributor head, through which the storage water is circulated through the ice supply 7 in order to use it for cooling a chiller.

Fig. 2 In addition to the circulation of the separation fluid, as described above, this can also be pressed back and forth between two storage containers B1 with an elastic "bubble" 27 and B2 with the "bubble" 28 and against the pressure of a gas filling 29 in the second storage container , whereby it absorbs the heat required for detaching the ice layer on the absorber 2 through the heat exchanger 30 from the storage water. This arrangement is driven by compressed air 26 and is therefore particularly unlikely to malfunction.

The cuts AA 'through the absorber 2 show in version I the evaporator body 16 , against the side surfaces of which the ice carriers 17 are pressed under the static pressure of the storage water 8 . The ice layer 18 forms on them. As soon as their permissible maximum thickness is reached, the separating fluid 20 is pumped under a pressure which is higher than the static pressure of the storage water 8 into the cavity 21 formed between the evaporator body 16 and the ice carrier 17 and lifts it from the surface of the evaporator from 17 a or presses it against a cutting grid 19 which has the task of mechanically crushing the ice 18 .

In version II this cutting grid is dispensed with, the ice carrier 17 , 17 a bulges out under the pressure of the separating fluid and breaks the adhering ice layer 18 before it is detached by the heat of the separating fluid.

Version III finally shows an absorber which dispenses with the evaporator body 16 . In its place there is a coil 16 a, which serves as an evaporator and which extracts the heat from the ice carriers 17 , 17 a by the stationary separating fluid 20 a, which also serves as a heat conductor here. As soon as the ice carrier 17 a is lifted only slightly against the static pressure of the water from the pipe coil 16 a, and in addition the cold resting separation fluid 20 a is replaced by inflowing, warm separation fluid 20 , the ice formation comes to a standstill. Since this construction has a particularly low mass, it also requires only a small amount of heat to detach the ice 18 from the ice carrier 17 a.

Analogous to the arrangements described above, the separation fluid can be identical to that so-called Brine "of a brine / water heat pump, the evaporator of which is connected to the Brine circuit is connected.

Fig. 3 shows how the "ice maker" 2 either flows directly through the cold brine or, as soon as the pump P1 is switched off and compressed air is blown into the container B1, from the warm separating fluid, which is already in the bladder V1, or warmed by the 4 ° C warm ambient water in the heat exchanger 30 .

Finally, Fig. 4 shows an arrangement in which a pump P2 circulates the separating fluid heated in the heat exchanger 30 until the ice layer has detached from the ice maker 2 .

This time can be changed by changing the electrical resistance Ω Measuring electrodes E1 and E2 are determined, which are caused by the formation or detachment of the Ice layer results.

Claims (6)

1. ice storage for a heat pump, characterized in that for the evaporator / absorber of the heat pump, a separating fluid, for. B. a water-glycol mixture is provided, which replaces an ice layer formed on the evaporator / absorber of the heat pump by heat input and / or its hydraulic / pneumatic pressure. 2. Ice storage according to claim 1, characterized in that the separating fluid through its heat Heat exchanger refers, which is arranged in the lower region of the water reservoir of the ice storage are and are washed by it. 3. Ice storage according to claim 1 and 2, characterized in that the separating fluid against the Flow resistance of a throttle is pumped into the absorber by a circulating pump, whereby a dynamic pressure builds up, which opposes the surface of the absorber, or parts thereof deforms the static pressure of the water supply and / or counteracts it together with the ice layer presses a cutter. 4. Ice store according to the preceding claims, characterized in that one or more expansion vessels are provided, the gas filling of which changes the volume of the separation fluid contained therein allowed and between their variable volumes the separation fluid with the help of another fluid, preferably compressed air is moved back and forth. 5. Ice store according to the preceding claims, characterized in that a cooling water circuit is provided which is the waste heat from an air conditioner or cooling system, or heat from one Solar collector enters the ice storage in the ice storage. 6. Ice storage according to the preceding claims, characterized in that a second for the heat pump Latent heat buffer storage is preferably provided with paraffin as the storage medium.