NL8002122A - YEAST RESERVOIR WITH ORGANS FOR THE CONTINUOUS OR INTERMITTING ROTATION OF ORGANIC SUBSTANCES. - Google Patents

Description

N / 29,578-dV / f.

Yeast reservoir with organs for the continuous or intermittent rotting of organic substances.

The invention relates to a yeast reservoir with means for the continuous or intermittent rotting of organic substances, consisting of a heat-insulated reservoir (rotting space), in which feed lines for the inlet of fresh material and discharge lines for the removal of the rotted material and in which means for heating and circulating the rotatable material are arranged.

Such a yeast reservoir serves for the production of methane gas from organic substances, such as farmyard manure, straw, feces, green material and household, garden and agricultural waste and waste from the food industry.

Furthermore, with the rotted material discharged from the yeast reservoir, a good hygienic point of view, a low odor-giving and nitrogen-rich natural manure is obtained.

Practical tests with homogenized fiber-rich rotting material have shown that this material does not sink, even with further rotting, such as, for example, municipal sludge, but rising. This means that the continuously operating decay reservoir can only work with decay material with a low specific weight, if floating material can also be removed. However, since it is not clear when setting up a biogas plant whether in the case in question only floating, only sinking, or also both ascending and sinking material is offered for the rotting process, it is possible for the fault-free, targeted sludge discharge of both alternatives to be possible. be provided.

The object of the invention is to design a yeast reservoir of the type mentioned in the preamble, such that both floating rotting material and sinking rotting material can be processed. The yeast reservoir according to the invention should furthermore be universally applicable, work with a high efficiency and be transportable.

According to the invention, the yeast reservoir is for this purpose characterized in that for the alternative discharge of float 800 2 1 22. In addition to the sludge discharge on the reservoir bottom, there is also a sludge discharge installed at the height of the upper limit of the decaying material.

An important feature of the present invention is therefore that in addition to a sludge discharge for discharging the rotted material from the reservoir bottom, a second sludge discharge is provided for discharging the rotted material floating in the yeast reservoir, so that the reservoir can be used universally.

10 The drain pipes of the bottom side and the top of the sludge drain are led out sideways through the tank wall in the top third of the tank, where they end up in a thrust vessel.

This propulsion vessel serves primarily as a gas shut-off or gas lock and must always be filled with liquid to above the top of the discharge pipes emerging therein. The propellant can be attached to the outer wall of the reservoir or be freely positioned in the immediate vicinity. A discharge pipe runs from the thrust vessel to the slurry pit. The propellant as a gas seal therefore corresponds to a siphon, which of course can also be designed in a different manner and is attached to the outer jacket by means of flanges.

In order to be able to keep the upper limit of the rotting material at the same height even at different gas pressures, the discharge pipe opening into the thrust vessel, which runs to the slurry pit, protrudes so far above the bottom of the thrust vessel, that with a pipe piece pushed over it ( sliding sleeve} the overflow edge can be adjusted as desired.

According to a preferred embodiment of; The invention blows the sludge discharge onto the reservoir bottom formed by a sludge guiding cone with the open side standing on the reservoir bottom, with lateral openings, into which a substantially vertical upright discharge pipe opens, the other end of which opens into a propellant below the upper limit of the rotting material.

According to the invention, the sludge discharge intended for the 40 1 floating rotting material at the height of 800 2 1 22 -3- of the upper limit of the rotting material is formed by a funnel arranged with the discharge side at this upper limit, which opens onto a discharge pipe, of which the the other end below the upper limit of the rotting material opens into a propellant. The bottom and top discharge pipes therefore both end in the thrust vessel, where these discharge pipes can optionally be closed by a slide. The slide can for instance be movable vertically, in which case the openings of the discharge pipes to be closed lie vertically one above the other.

According to the invention, the slide can also be arranged horizontally displaceable, in which case the openings of the discharge pipes are horizontally adjacent to each other.

According to the invention, the sludge discharge on the reservoir bottom and at the upper limit of the rotting material can be formed by forming a through tube with lateral openings in the region of the reservoir bottom and of the upper limit of the rotting material from beyond the reservoir bottom. the top of the gas clock cover is lined, with openings for the gas outlet being provided below the gas clock cover, while the pipe outside the gas clock cover is gastight and in that an at least substantially horizontal pipe connects to the through pipe below the upper limit of the rotting material, the other opening of which opens into a thrust vessel. In this way a particularly simple construction of the bottom and top sludge discharge is obtained, since essentially only a vertical upright tube with a side branch has to be fitted in the reservoir.

It is preferable if a manhole is provided in the yeast reservoir for installation and any repair, which may be provided in the gas clock cover near the reservoir wall, so that the operator can enter the upper sludge discharge funnel when entering the reservoir. pass. However, it is also possible to install the manhole in the reservoir wall. This achieves the advantage that the entire reservoir cover is welded gas-tight in the region of the gas supply space and has no detachable connection. In addition, the submersible pump can be easily mounted at the installation site, which is favorable for transport. Furthermore, the pump can be exchanged without problems and without danger in the event of external faults, after the contents of the reservoir have been drained to the mounting height.

Furthermore, an important feature of the invention is that the high-efficiency yeast reservoir to be described hereinafter is readily transportable on public streets with conventional means of transport, since the diameter of the reservoir lies within the officially prescribed limits, for which no special license is required. . This allows the yeast reservoir to be fully prepared in series at the workplace. In that case, only the pipes for the power supply, hot water circulation 15 and the supply and discharge pipes for the rotting material must be connected to the installation site. These small dimensions are achieved in particular by the use of a thermophilic yeast method, i.e. a heating of the reservoir contents to above 50 ° C.

The invention will be explained in more detail below with reference to the drawing, which shows an embodiment of the invention and which will discuss some important advantages and features of the invention.

The yeast reservoir shown has a cylindrical cross-section with an inner wall 1a, an outer wall 1b and an intermediate insulation 1c. A gas clock cover 2a is provided on the reservoir 1a, 1b, which has an inner wall 2b and an outer wall 2c. The gas clock system 2a 30 closes off the gas supply space 2, which is above the upper limit 3 of the decaying material. The yeast substrate is pumped into the rotting chamber 1 via a fresh material feed 4 and flows out of the outlets 4a until the reservoir is filled approximately to the upper limit 3. During operation, a continuous circulation of the rotting material takes place, because a submersible pump 25 is arranged in the rotting space 11, which via a suction base 30; sucks the rotting material and returns this material to the reservoir through a circulation pipe 8 and nozzles 8a. According to a favorable embodiment of the present invention, a first nozzle 8a is provided in the vicinity of the bottom, from which the rotting material flows out in the direction of the arrow 32, while in the gas storage space 2 a second nozzle 8a is provided, which is directed towards the floating layer forming at the upper limit 3, so that this floating layer becomes smaller due to the rotting material emerging in the direction of the arrow 31.

The reservoir bottom 1f is conically shaped as a decay space bottom 1g, on which a sludge guide cone 12 with openings 12a located at the bottom is placed. The rotting sludge which ends up in the middle of the bottom lg can then finally be removed via the discharge pipe 5 for the rotted finished sludge in the direction of the arrow 33.

The rotting sludge is brought to a relatively high temperature by means of a heating hose 10, which heating hose 10 is connected via a heating supply 10a and a return line 10b to a hot water supply.

The gas forming in the gas supply space 2 can be taken off over a gas discharge pipe 9, the pyramid-shaped heating hose being connected over the supply 10a and the return pipe 10b to a hot water supply. A convection flow is achieved by the heating arranged above the sludge guide cone 12, whereby the existing reservoir space is utilized better. The use of the thermophilic yeast method (above 50 ° C) allows the use of a smaller and thereby transportable yeast reservoir. Of course, the yeast substrate can also be heated outside the reservoir.

The sludge discharge 5, 12, 12a located on the bottom side is explained below:

As already noted, it serves; sludge discharge for removing the rotted material, which sinks to the bottom of lg. The one end of the discharge pipe 5 opens into the sludge guiding cone 12, while the other end with its opening 21 opens into the thrust vessel 26. Now that the rotted sludge deposited on the bottom lg has to be removed, the opening 21 becomes the slide 34 closing off the discharge pipe 5 in the direction of the arrow 35 is moved upwards, so that the opening 22 of the discharge pipe 5a located at the top is closed. Due to the liquid pressure (the upper limit 3 of the rotting material lies above the opening 21 of the discharge pipe 5) 5, the rotting material located on the bottom 11g is pressed into the discharge pipe 5 in the direction of the arrow 33 and flows into the thrust vessel 26. If the openings 21, 22 of the discharge pipes 5, 5a are continuously below the upper limit 3, the propellant vessel 26 forms a gas seal, wherein a vent pipe stub 44 is arranged in the upper part of the propellant vessel 26. The material flowing in the thrust vessel 26 fills the thrust vessel until the material comes above the edge 38 of a sleeve 36 slidable over the discharge pipe 5b and runs away via the discharge pipe 5b in the direction of the arrow 39.

As already noted above, the sliding sleeve 36 serves to maintain a constant height of the upper limit 3 of the rotting material independent of the gas pressure within the gas supply space 2. If the gas pressure is 0 in this gas supply space, then the rotting space 1 and the same liquid height in the thrust vessel 26. If the gas pressure in the gas supply space 2 is, for example, a 250 mm water column, the liquid level in the propellant vessel is higher, in theory about 250 mm. The shifting direction 25 of the sleeve 36 in the direction of the arrow 37 therefore adjusts according to the gas pressure within the decay space 1.

According to the invention, the shifting of the sleeve can take place automatically in accordance with the gas pressure in the gas supply space 2. Of course, a shifting by hand is also possible. A certain maximum pressure is permitted in the yeast reservoir. If it is established on the basis of the gas pressure gauge that the maximum pressure is exceeded, the liquid level in the yeast reservoir (upper limit 3) must be reduced. To this end, the sleeve 36 is slid downwards, so that the rim 38 also comes down and the liquid level in the thrust vessel 26 drops, since more liquid now flows out of the thrust vessel via the tube 5b in the direction of the arrow 39.

The liquid level in the thrust vessel 26 should never be so low that the openings 21, 22 of the discharge pipes 5, 5a become exposed 40, otherwise the gas from the gas supply space 2 800 2 1 22 -7- will enter the thrust vessel 26 pressed.

To this end, for example, the openings 21, 22 of the discharge pipes 5, 5a can be arranged horizontally next to each other, in which case the slide 34 can also be displaced horizontally. In this way a lower liquid position in the thrust vessel 26 can be achieved without the openings 21, 22 being able to fall below the upper limit 3 of the rotting material.

The sludge discharge 5a, 12b at the top is described below.

This sludge discharge at the upper limit 3 of the rotting material is formed by a funnel 12b, the discharge side 40 of which is arranged at the height of the upper limit 3 and which opens into the discharge pipe 5a, of which the opening 22 located at the other end is below the upper limit 3 opens into thrust vessel 26. The funnel shape of the funnel 12 is important because the bottom 45 of the funnel 12b hereby forms an oblique plane. The ascending fermentation material is led upwards along this oblique plane and there collides with the floating layer, if any, at the upper limit 3. As a result, a refraction of the rotting material takes place here over the edge 46 of the funnel 12b, as well as a degassing at the edge 46, so that the material of the floating layer in broken form falls into the funnel 25b and is led in the direction of the arrow 41 via the discharge pipe 5a to the thrust vessel 26. In this way, an optimum comminution of the floating layer is achieved in conjunction with the nozzle 8a of the circulation pipe 8.

The funnel 12 is attached to the gas clock cover 2a with braces 12c.

In the drawing, the slide 34 is in the lowest position and closes the opening 21 of the discharge pipe 5. In this case, therefore, the material collected at the upper limit 3 is discharged from the yeast reservoir via the funnel 12b and the discharge line 5a.

Instead of the funnel 12b with the edge 46 and discharge side 40, a stirring screw or another mechanical comminuting device can also be used for crushing the floating layer. Furthermore, a number of nozzles 8a 40 can also be provided to crush the floating layer by 800 2 1 22 -8 "by means of the jet emerging from the nozzles. The discharge side 40 of the funnel 12b can further be provided with protrusions and teeth, in order to ensure an additional mechanical reduction of the material falling into the funnel 12b. Alternatively, the submersible pump 25 may also be placed outside the yeast reservoir.

According to the invention, a ball tank can be used instead of a cylindrical reservoir. Instead of a fixed connection between the gas clock cover 102a and the vertically upright reservoir wall 1a, 1b, 1c, a gas clock cover 2a floating on a liquid lock can be used.

800 2 1 22

Claims (15)

1. Yeast reservoir with organs for the continuous or intermittent rotting of organic substances, consisting of a heat-insulated reservoir (decay space), into which feed lines for the inlet of fresh material and discharge lines for the removal of the rotted material end and in which members are provided for heating and circulation of the decaying material, characterized in that for the alternative discharge of floating or ascending decaying material, in addition to the sludge discharge 10 (5, 12, 12a) on the reservoir bottom (1f), also at the level of the upper limit ( 3) a sludge drain (5a, 12b) is provided of the rotting material. Yeast reservoir according to claim 1, characterized in that the sludge discharge (5, 12, 12a) on the reservoir bottom (1f) is formed by a sludge guide cone (12) with open openings on the reservoir bottom with lateral openings (12a) into which a substantially vertically upright discharge pipe (5) opens, the other end (21) of which opens below the upper limit (3) of the rotting material into a thrust vessel (26). Yeast reservoir according to claim 1 or 2, characterized in that the sludge discharge (5a, 12b) at the height of the upper limit (3) of the rotting material is formed by one with the discharge side (40) at the height of this upper limit. (3) arranged funnel (12b), which opens onto a discharge pipe (5a), the other end (22) of which opens below the upper limit (3) of the rotting material into a propellant (26). Yeast reservoir according to claim 1, characterized in that the sludge discharge on the reservoir bottom and at the height of the upper limit (3) of the rotting material is formed by a continuous tube with lateral openings in the region of the reservoir bottom (1f). and from the upper boundary (3) of the decaying material from the reservoir 35: bottom (1f) to the top of the gas clock cover (2a), with openings for the gas outlet below the gas clock cover (2a), while the pipe outside the gas clock cover (2a) is closed in a gastight manner and because at least 800 2 1 22 is below the upper limit (3) of the rotting material. “-10- connect a pipe that runs almost horizontally to the continuous pipe, the other opening of which opens into a thrust vessel (26) (not shown in the drawing). Yeast reservoir according to any one of claims 5 to 4, characterized in that the openings (21, 22) of the discharge pipes (5a, 5) opening into the thrust vessel (26) can be closed optionally by an electric, hydraulic or the manually operated slide, which is fitted in the thrust vessel (26). Yeast reservoir according to any one of claims 1 to 5, characterized in that, in order to keep a constant upper limit (3) of the rotting material in the rotting space (1) constant, irrespective of the gas pressure in the gas supply space (2) in the thrust vessel (26) and a discharge member (5b, 36, 38) with variable discharge height is provided. Yeast reservoir according to claim 6, characterized in that the discharge member (5b, 36, 38) in the thrust vessel (26) is formed by a discharge pipe (5b) opening into the thrust vessel (26), on which a vertically displaceable sleeve (36) is fitted. Yeast reservoir according to any one of claims 1 to 7, characterized in that a submersible pump (25) (or an apparatus outside of this space) is arranged in the rotting space (1), which feed the rotting material via circulation pipes (8). circulates in the rotting space (1). 9. Yeast reservoir according to claim 8, characterized in that above the upper limit (3) of the rotting material a circulation pipe (8) is provided with a nozzle (8a) directed towards the supernatant layer of rotting material. Yeast reservoir according to claim 1, characterized in that the dimensions of the thermophilically heatable yeast reservoir are adapted to the usual transport conditions (maximum diameter 1000 mm and maximum height 7500 mm). Yeast reservoir according to claims 1 and 10, characterized in that the pyramidal heating hoses (10) are arranged between the sludge guide cone (12) and the upper funnel (12b). 800 2 1 22. "-11- Yeast reservoir according to claims 1, 10 and 11, characterized in that the spaced heating hoses (10) are located in the region of inflow openings (4a, 8a) for the yeast substrate. Yeast reservoir according to any one of claims 1-12, characterized in that a circulating reinforcement (23) is arranged in the reserved bottom (1f), which simultaneously supports the sludge guiding cone (12) and the heating cone (12). 24) serves. Yeast reservoir according to claims 1 and 13, characterized in that the reinforcement (23) has guide surfaces (24) which are directed towards the base, respectively. the openings (12a) in the sludge guide cone (12). Yeast reservoir according to claim 1, characterized in that the thrust vessel (26) is connected by flange connections to the casing of the yeast reservoir. 800 2 1 22 i