DE674620C - Method and device for space heating by means of air - Google Patents

Description

Method and device for space heating by means of air The invention relates to a method and a device for space heating by means of air, the man his running in the negative pressure area, one expansion and one. compression can run through a no-closing cycle.

The known methods working on this basis have one low efficiency. The amount of air drawn in from the outside air is also included the expansion in an expansion cylinder cooled to such low temperatures, that feudigkeit is eliminated from it, which on the one hand relate to the impeccable Working of the piston 'in the expansion cylinder has a disruptive effect and the @ on the other hand can lead to the formation of frost on the outside of the cylinder. Also wise the known devices on its structure, the considerable leakage and friction losses allows.

The purpose of the invention is its method and a device for space heating to create by means of air, with greater efficiency, d. H. a better relationship between the heat that can be used for space heating and that required for its generation Workload.

According to the invention, the heating air is used in the cycle can run through, for the purpose of bringing about: an expansion with as constant as possible Temperature and compression if possible without either heat input or heat dissipation the expansion stroke performed so slowly and the compression stroke performed so quickly or the heat transfer during expansion is so favorable and during compression so poorly held that the heating air only heats out during the cycle the outside air surrounding the room to be heated.

To carry out this process, for. B.: a device is used are, the .A single arranged in the outside air surrounding the room to be heated Has cylinder in which the hot air is driven by a cam or drag crank drive controlled piston slowly expands and then quickly compresses to subsequently to be led into the room to be heated.

With the same success, a device can also be used which an expansion cylinder in the outside air surrounding the room to be heated arranged and compared with. large heat transfer surfaces to the volume of its working chamber is provided, and includes a special compression cylinder into which the heating air gets out of the expansion cylinder and only allows its low heat exchange.

The expansion cylinder or the expansion compression cylinder is preferably designed as a bellows at one end with the Piston is firmly connected. The cylinders can be equipped with special additional devices, such as fans, sprinklers, reheaters or the like, be provided, the heat transfer between the outside air and the circulating air Promote heating air.

The subject of the invention is explained and illustrated in the drawings, namely, Figs. i and 2 show two graphical diagrams of the method according to FIG Invention, Fig.3 a device according to the invention in plan view and Fig. ¢ the Cam drive of the device in side view.

In the procedure shown in Fig. I, one is left out the outside air sucked into an expansion cylinder amount of air from the pressure pl and the temperature T1 in the cylinder to the pressure p2 so expand. (Line i-2), that they get as much heat as possible from the outside air surrounding your cylinder absorbs, so that the expansion takes place with as constant a temperature as possible. This achieves on the one hand that the heat content of the heating air is as large as possible so that a high groove heat drops at the end of the cycle, and on the other hand is avoided that temperatures occur in the expansion cylinder at which a disturbing excretion of humidity inside the cylinder and frost could form on the outside of the cylinder.

The heating air then comes out of the expansion cylinder at pressure p2 at point 2 into the compression cylinder. If necessary, additional heat can be supplied Q an increase in the volume of the air can take place at constant pressure (Line 2-2 '), which means that the compression cylinder has a larger bore than the expansion cylinder has. However, such a change in the state of the air is not intended take place, then both cylinders can have the same bores and with the same Piston stroke.

In the compression cylinder, the air is as possible without discharge of Heat Q2 essentially compressed to the initial pressure p1 (line 2-3 or 2'-3 '), so that it heats up to the temperature T3 or T3. The warm air then gets in from the compression cylinder into the room to be heated, where it gives off the heat Q i (Line 3-i resp.

The lower the heat dissipation Q, along the line 2-3 or 2'-3 ', the higher the final temperature T; or T3 'achieved. This maximum temperature is therefore only different from those during the cycle for a given pressure limit pl and p2 heat quantities Q1 and Q2 that are supplied or removed. The relationship of the to and The dissipated heat-91- can be regulated in that both the expansion cylinder as well as the compression cylinder provided with ribs and these by means of a fan be blown on. Appropriately, the expansion cylinder becomes strong and the compression cylinder poorly ventilated or not at all ventilated. It does not matter by what means the desired ratio of the amount of heat added during expansion to that at the amount of heat dissipated during compression is achieved. In place of the ribs and fan can e.g. B. also the following means can be used: sprinkling or humidification of the cylinder surfaces in order to achieve an increased heat transfer, enlargement of the cylinder surfaces, creating humidified and porous surfaces around the Use evaporative cooling for cooling.

If a certain starting temperature Ti is assumed, the end temperature T3 of the cycle is completely determined when the pressure ratio f1, the heat Q1 supplied to Ps during the expansion and the heat ratio Q2 are given. For a given device, the two work L1 (expansion) and L2 (compression) or the associated heat quantities Q1 and Q; # are essentially dependent on the heat transfer coefficient k, and this in turn depends on the flow rate of the forced heating or cooling air.

Since the heat Q passing through the cylinder walls depends only on the passage area F, the temperature difference T "-Ti and the heat transfer coefficient k, but these quantities represent those values which determine the flow strength of the heat, T3 can be defined as a given pressure difference and the different flow rates of heat as a function of: It is clear that the cycle process shown in Fig. i cannot have any thermodynamic losses of importance line 2-3 and 2'-3 'forms an adiabatic, then they give for a particular given ratio p' while the highest ER pz available round the clock temperature T.- "However, the greatest effort. This is nevertheless about 4oo, 1o smaller than in the known processes.

This isotherm-adiabatic cycle provides the greatest heat yield per kilogram of air with the smallest cylinders, however, has: not the most favorable coefficient of performance. In the following, this is to be proven with the aid of Fig.

For the given expansion line 1-2, the isopykne 2-3 (line of equal density, v constant) is assumed as the compression line, which is still above the adiabatic. The distance 3-1 is proportional to the volume difference V3-V "of this the temperature uint, difference T3-Tl and thus the amount of heat Q obtained; the hatched area is proportional to the work AL . If the ratios are chosen so that the curve 2- 3 'arises, the content of the area r-2-3' decreases faster than the distance 1-3 ', since the curve 2-3' is concave outwards 2-3 'of the adiabatic.

The above-mentioned dependence of the final temperature T3 on the pressure differed and the difference in heat flow strengths also offers the possibility of perform the entire cycle in a single cylinder.

Figure 3 illustrates such an arrangement. There is a with i b.algartiger cylinder, which is attached to a stand 2 of the base plate 3 is. With the cylinder i is a hollow piston q. at point 5 solid and airtight tied together. On the piston .1. the hollow piston rod guided in bearing n6 closes 7 at. In the working space R of the cylinder open on the one hand the z. B. as uncontrolled Fall valve formed exhaust valve 8 and on the other hand that in the bottom of the piston built-in suction valve under the action of a spring i o g. The latter is mediated by the bumper i i, the lever 12 and the roller 13 of the Cam disk I q. controlled. The cam disk 14 sits on the drive shaft 15, which also carries a cam disk 16, which on the arm 17 of the piston rod 7 mounted roller 18 controls the piston movement.

Fig.q. shows the two cam disks 1 4th and 16 in view. With a to f are the individual sections of the edges of the cam disk, en, where a is the suction and expansion section, b is the compression section and c the rest section of the piston q. controlling cam disk 16 means while d the opening section, e the closing section and f the resting section of the das Valve g controlling cam disk 14 represents.

During the outward stroke, air is sucked in through the inlet valve g, and by controlling this valve, the amount of air in the cylinder space R and thus the negative pressure p2 is regulated. This part of the stroke (sections d and e) is short measured. As soon as the valve g is closed, one lets out the air at the same time expand slowly with strong heat supply from the outside. The return of the piston and thus the compression of the air then takes place very quickly. As the heat transfer surfaces for the expansion stroke and the compression stroke are the same, the flowing through depends The amount of heat essentially depends on the time it takes for the work in question the device is available. There is therefore little heat during compression flow out, while a lot of heat can flow in during expansion, creating the desired Final temperature T3 is reached. This is the temperature at which the air passes through the valve 8 applied to the room to be heated.

The formation of the cylinder as a bellows, that with the piston without the Presence, a gap interacts, reducing leakage losses and losses through Friction can be avoided, eliminating the main disadvantages of the known Devices. For example, a machine was used for his effort of io PS, which were measured on a pendulum dynamo, only an idling effort from q. mkg / sec. established. In addition, a bellows-like cylinder provides the possibility of to keep the working air in constant contact with the moving bellows walls, whereby the heat transfer due to the large surfaces is often greater than with ordinary ones Ribs.

The losses of his device of this type are limited to that Friction losses in the gearbox and, if applicable, valve and flow losses, which, however, are reduced to a small amount by structural measures can. The negative pressure area is only influenced by the inflow of heat. All other otherwise essential influences are eliminated.

A device of the type described above, which after a Circular process according to Fig. I works, theoretically offers the possibility of a temperature difference T3-T, of q.o ° 18 to 2 times the workload than to gain heat, and even if all sources of loss are taken into account the amount of heat is not less than 12 to i 5 times the workload sink. A large amount of heat is obtained with little mechanical effort.

By. , simple reversal of the direction of flow of the circular process the device can also be used for room cooling. This is z. B. by Reversal of the drive and in special cases by changing the cam disks achieved.

Claims (1)

PATENT CLAIMS: i. Method of space heating by means of air, according to which atmospheric air has a lean expansion and a low pressure area undergoes a cycle including compression, thereby; marked, that in order to bring about its expansion with as constant a temperature as possible and compression as far as possible without adding or removing heat - either the expansion stroke so slowly and the compression stroke so fast! the heat transfer takes place iod-er So cheap during expansion and so bad during compression is kept that the heating air only heat from the during the cycle outside air surrounding the room to be heated. z. Device for implementation of the method according to claim i, characterized by linen only in the To be heated room surrounding outside air arranged cylinder (i), in which the Heating air by means of a cam or drag crank drive (14, 18) controlled Piston (q.) Slowly expands and rapidly compresses to subsequently move into the room to be heated to be guided. 3. Device for carrying out the process according to claim i, characterized by an expansion cylinder in the The outside air surrounding the room to be heated is arranged and compared to the room content its working chamber is provided with large heat transfer surfaces, and a special one Compression cylinder into which the heating air from the expansion cylinder arrives and which only allows a small amount of heat exchange. q .. system according to one of the claims? or 3, characterized in that the expansion cylinder or the expansion compression cylinder Bellows-like (i), formed and firmly connected at one end (5) to the piston (q.) is. 5. Plant according to one of claims z to q., Characterized by the arrangement of the heat transfer between the heating air passing through your cycle and the outside air-promoting, per se known additional devices, such as blowers, sprinkling devices: Reheaters or the like.