RU2132917C1 - Method for continuous treatment of concrete mixes - Google Patents

Abstract

FIELD: construction engineering. SUBSTANCE: device is intended for treating concrete mixes prior to placing them into form or shuttering in production of sectional concrete structures or in erection of cast-in-place concrete structures. Device has charging bin and heating chamber adjacent to charging bin. Heating chamber is vertical and adjoins charging bin in resilient and hermetic manner. Secured externally on body of heating chamber are vibrator and discharge spout. Fastened on internal electrically insulated surface of heating chamber are electrodes which are connected to three-phase alternating current supply network. Electrodes are rectilinear and are of triangular configuration in their cross-section. Sum of internal angles of electrode peaks facing towards center is equal to 360 deg. Adjacent faces of neighboring electrodes are parallel to each other. Discharge spout which functions as adjustable gate is made in the form of round fitting. Internal diameter of discharge spout corresponds to internal diameter of heating chamber. Lower end of discharge spout is limited by two planes which are symmetrical relative to central horizontal axis. Planes are inclined to vertical line at angle not over 45 deg. Seated between these two planes are movable shutters sliding along guide members. Device is easy to manufacture and operate. It affords wide range of productive capacity and of concrete mix heating temperature. EFFECT: higher efficiency. 3 cl, 5 dwg

Description

 The invention relates to the field of construction production and can be used in the processing of concrete mixtures before laying in form or formwork in the manufacture of prefabricated or erection of monolithic structures.

 A device for continuous electrical heating of a concrete mixture containing a chamber having a rectangular cross-section with a hopper and estrus mounted on it and transporting vibratory trays in steps, equipped with corner electrodes placed on electrically insulated bottoms [1].

 The disadvantages of this device are as follows.

 The device in operation is difficult and unreliable: access to cleaning concrete mixture is difficult; due to a sufficiently large range of mobility of the concrete mixture in production conditions, it is practically not realistic to synchronize the change in the angle of inclination of the trays with the change in the rheological properties of the concrete mixture. Open surfaces of the concrete mixture lead to its dehydration during processing, which worsens the conditions for cement hydration; with a triangular shape of the electrodes located on the flat base of the tray, the interelectrode distance changes along the height of the layer of the processed mixture, which leads to an increase in the current density at the bases of the electrodes, and, consequently, to uneven heating of the mixture.

 Known concrete duct with electrical heating of the concrete mixture, comprising a housing with an insulated inner surface at the electrical heating area and three strip electrodes 0.3 to 0.35 wide of the inner diameter of the housing evenly located on it along the helix. A vibrator is installed on the body of the heating section of the concrete duct. Each of the electrodes is connected to one of the phases of a three-phase alternating current [2].

The disadvantages of the device are due to the limited size of its inner diameter. Concrete balers usually have a diameter of 100 - 150 mm. Calculations show that with a device productivity of, for example, 6 m ³ / h, which is most suitable for the production conditions, and with a mixture heating time of 2 minutes, which is necessary for heating a large aggregate of the mixture, the length of the heating part of the concrete pipeline is about 12 m. This length is practically unacceptable due to the difficulty of cleaning it. With an increase in the diameter of the heating section of the concrete conduit, there will be a large uneven distribution of the current density over the cross section of the volume of the processed mixture.

 The closest technical solution to the claimed device is a device for continuous processing of concrete mixture before laying into the formwork, containing a vertically arranged case of circular cross-sectional shape, equipped with a discharge chute and a loading hopper mounted above the case, a chamber for heating the concrete mixture with electrodes placed on an electrical insulating coating, infrared emitters located inside the housing, and vibrators mounted on the heating chamber, which is equipped with In the upper part of the casing with a vacuum pump, the heating chamber is made in the form of two pipes coaxially installed inside the casing, the outer pipe is rigidly connected to the loading hopper, and the inner one is mounted with the possibility of oscillation in the vertical plane by means of a vibrator and connected to the vacuum pump, the insulating coating is located on the pipe surfaces facing each other and has roll-shaped protrusions located along a three-way helix, between which electrodes are placed, made lamellar, and the turns of the roller-shaped protrusions of the outer pipe relative to the turns of the roller-shaped protrusions of the inner pipe are offset by half a step. In addition, the device is equipped with a funnel-shaped element fixed to the end of the inner pipe, the cavity of which is facing the discharge chute [3].

 The main advantage of the device: the combination of heating and vibration of the mixture, laid the foundation for its work, can dramatically intensify the processes of cement hydration in the early stages of concrete hardening; the use of line voltage (380 V) on all electrode groups allows, all other things being equal, to ensure a sufficiently high performance with a relatively small size of the device.

However, this device has disadvantages. So, the presence of protrusions between the electrodes is not advisable for the following reasons:
- the protrusions are an artificial obstacle to the movement of electric current between adjacent phases on each of the pipes (external and internal),
- the difficulty of cleaning internal surfaces having roller-shaped protrusions;
- the complexity of manufacturing the inner surfaces of the heating chamber, equipped with spiral electrodes and roller-shaped protrusions.

 The presence of a central pipe also complicates the operating conditions of the device in terms of its cleaning. Placing the central pipe mounting system, its drive and vibrators above the hopper turns the feed hopper into a receiving funnel, the small volume of which does not allow to create a supply of concrete mix, which provides the necessary pressure for stable operation of the device. It is also problematic to load the hopper with concrete mixture in building conditions.

 Rigid coupling of the housing of the heating chamber and the hopper causes separation of the concrete mixture in the hopper under the influence of a vibrator located on the housing.

 There is a risk of clogging of the dehydrated concrete mixture in the area of the outlet.

 In real conditions of construction production, it is rather problematic to provide two sources of three-phase alternating current provided for the operation of the device.

 The disadvantage of the prototype is also the limited ability to change the performance of the device while maintaining the set parameters for heating the mixture.

 The main task to which the invention is directed is to increase the manufacturing and operational manufacturability of the device, primarily in terms of operability and ease of maintenance, and to increase the range in terms of productivity and heating temperature of the mixture.

 To solve this problem, a device for continuous processing of concrete mixtures is proposed, which, like the prototype, contains a loading hopper, a vertically arranged round-shaped heating chamber paired with it, on the casing of which a vibrator and unloading heat are fixed on the outside, and electrodes connected to three-phase alternating current network.

Unlike the prototype, in the proposed device, the electrodes are placed only on the internal electrically insulated surface of the heating chamber, i.e. the central tube is excluded, and the electrodes, each of which is connected to one of the phases of the three-phase AC network, are made rectilinear, are located along the camera, have a triangular cross-sectional shape, the sum of the internal angles of the vertices of the electrodes facing the center is 360 ^o , while the camera heating is associated with a loading hopper through elastically sealed elements, and the unloading heat, performing the function of an adjustable shutter, is made in the form of a round nozzle, the inner diameter of which corresponds to the inside thereto diameter of the heating chamber and the lower end is limited by two symmetrical relative to a central horizontal axis planes which are inclined to the vertical at an angle of not more than 45 ^o, in which there are movable flap displaceable on rails attached to the housing unloading chutes, with the possibility of synchronous reciprocation from the drive, also mounted on the body of the unloading estrus.

Between the triangular electrodes can be installed flat (plate) electrodes. In this case, various electrode connection schemes are possible:
- all electrodes (both triangular and plate) are connected to phase wires of a three-phase alternating current network;
- triangular electrodes are connected to phase wires, and plate electrodes are connected to the neutral wire of a three-phase AC network,
- plate electrodes are connected to phase wires, and triangular electrodes are connected to the neutral wire of a three-phase AC network.

 The essence of the invention lies in the fact that the required area of the current-collecting electrodes and the required distance between them, necessary for the efficient heating of the mixture, are provided not by placing part of the electrodes on the central pipe (as in the prototype), but by changing the design of the electrodes placed only on the inner surface of the heating chamber body. The rejection of the central pipe significantly simplified the design of the device and, most importantly, made it possible to increase the convenience of its operation (no need to remove the pipe to clean the internal volume of the heating chamber). The area of the collector electrodes not only did not decrease compared to the prototype, but also increased. Indeed, two legs (two sides) of a triangular electrode are always larger than the part of the arc of the chamber body to which they adjoin. The area of the electrodes can also be increased by placing plate electrodes between the triangular electrodes. The increase in the area of current-collecting electrodes allows, ceteris paribus (while maintaining the performance and heating temperature) to reduce the height of the heating chamber, which also improves its cleaning conditions.

Compliance with the condition under which the sum of the internal angles at the vertices of the electrodes forming the electrode sections is 360 ^° ensures parallelism of adjacent faces of removable triangular electrodes. This, in turn, ensures uniform heating of the mixture and improves the cleaning conditions of the heating chamber.

 The presence of several electrode sections with an equidistant distance between the planes of the collector faces of the electrodes allows you to connect them to a three-phase AC network according to various schemes, which, in turn, provides the possibility, all other things being equal, (with the same dimensions of the heating chamber, the area of the electrodes and interelectrode distances) significantly increase the range of changes in the performance of the device and the temperature of the heating mixture. To obtain maximum performance and temperature, all electrodes are connected to the phase conductors of a three-phase AC network.

 Minimum values of productivity and temperature can be obtained by connecting triangular or plate electrodes to the phase conductors of a three-phase AC network. In this case, plate or triangular electrodes must be connected to the neutral wire of a three-phase AC network with a grounded neutral.

 The smooth inner surface of the heating chamber, on which the collector electrodes are placed, contributes to a better passage of electric current through the concrete mixture between adjacent phases, because eliminated the artificial barrier in the form of a roller-shaped protrusion, which takes place in the prototype. In addition, the cleaning conditions of the device are improved, which is very important for its viability.

 Suspension of the heating chamber to the loading hopper on vibration-insulated rods and the presence of elasto-tight coupling between the hopper and the heating chamber minimizes the transmission of vibration to its housing, which prevents the mixture from stratifying.

 The invention is illustrated by drawings, which depict: in Fig.1 is a General view of the device, Fig.2 is a cross section of a chamber for heating a concrete mixture equipped with triangular electrodes; figure 3 is a cross section of a chamber for heating a concrete mixture equipped with triangular and plate electrodes when connecting all the electrodes to the phase wires of a three-phase AC network; figure 4 is the same, when connected to the phase wires of the triangular electrodes, and plate - to the zero wire; figure 5 is the same, when connected to the phase wires of the plate electrodes, and triangular to the neutral wire.

 A device for continuous processing of concrete mixtures contains a loading hopper 1, a heating chamber 2, equipped with vibrators 3 and a discharge chute 4. On the insulating pipe 5, a housing 7 of the heating chamber 2 is fixed by means of a crimping sleeve 6, which is suspended from the hopper 1 by means of rods 8. shock absorbers 9 are provided for vibration isolation of the hopper 1 from the heating chamber 2, and the tightness between the heating chamber and the hopper is ensured by means of elastic gaskets 10. The discharge chute 4 is attached to the housing of the chamber 2.

The inner diameter of the unloading estrus 4 corresponds to the inner diameter of the heating chamber 2. The lower end of the unloading estrus 4 is cut along two planes intersecting along the central horizontal axis of the estrus and inclined to the vertical axis at an angle of at least 45 ^o . Using a drive (not shown) in these planes along the guides 11 attached to the body of the discharge chute 4, the shutters 12 are moved.

On the inner surface of the insulated pipe 5 of the heating chamber 2 there are placed electrodes 13 made linear and having a triangular cross-sectional shape. Each of the electrodes, the number of which is a multiple of three, is connected to one of the phases of a three-phase AC network (Fig. 3). The sum of the internal angles of the vertices of the electrodes facing the center is 360 ^o , i.e., the adjacent faces of adjacent electrodes are parallel to each other.

 The performance of the device can be improved without increasing the height of the heating chamber 2 by increasing its diameter. In this case, it becomes possible to place plate electrodes between the triangular electrodes 13. When connecting the triangular and plate electrodes to the phase wires (Fig. 3), the device performance and the mixture heating temperature will have maximum values for this device size, because a linear current with a voltage of 380 V will pass through the entire volume of the mixture

 When connecting triangular (or plate) electrodes to the neutral neutral ground wire, and plate (or triangular) electrodes to phase conductors, the device’s performance and (or) the mixture heating temperature will decrease, because the operating voltage will be phase, i.e. 220 V (Fig. 4, Fig. 5).

 Electricity is supplied to the collector electrodes through a power cabinet in which a control panel is mounted (not shown in the drawing). The device is equipped with a temperature sensor (not shown in the drawing).

 The device operates as follows.

 In the initial position, the movable shutter 12 is closed. The concrete mixture prepared and delivered to the place of laying according to traditional technology is loaded into the hopper 1. After applying voltage to the electrodes 13 and (or) 14, the vibrators 3 are turned on. Under the influence of gravity and vibration, the concrete mixture enters the heating chamber 2, in which concrete mixture, as an electric current passes through a conductor with a certain electrical resistance between each of the phases (when connecting the electrodes of figure 3) or between each of the phases and zero (when connecting the electrodes of figure 4 and figure 5). In accordance with the Joule-Lenz law, the concrete mixture is heated. Equidistant distance between adjacent faces of adjacent electrodes provides a uniform distribution of current density, therefore, uniform heating of the mixture. Heating the mixture is accompanied by simultaneous exposure to the mixture of vibration and excessive pressure. The latter is inevitable and takes place, since heating the mixture leads to a sharp increase in the volume of the vapor-air medium, which in a closed volume causes the appearance of excess pressure. The combined effect on the concrete mixture of temperature, vibration and excess pressure activates the concrete mixture, contributes to an increase in its gel component, which subsequently increases the strength of concrete.

 After the concrete mixture reaches the required temperature, the shutters 12 are synchronously opened by an amount providing the required performance.

 In the event of an emergency stop, for example during a power outage and during long interruptions, the shutters 12 are diverted to the highest position, which provides free access to the inner surfaces of the heating chamber 2 for cleaning.

 Thus, the proposed device can improve its manufacturability both at the manufacturing stage and in the process of its operation. At the same time, the possibility of changing its parameters in terms of productivity and temperature of heating the mixture inherent in the device allows to increase the scope of its application. In addition, the presence of plane-parallel faces of the collector electrodes makes it possible to increase the uniformity of the distribution of electric current density, and hence the uniformity of heating the mixture.

Sources of information
1. USSR author's certificate N 1270005, B 28 B 17/02, 1986.

 2. USSR author's certificate N 1152900, B 65 G 53/32, 1985.

 3. RF patent N 2008216, B 28 V 17/02, 1994.

Claims (4)

1. A device for the continuous processing of concrete mixtures, comprising a loading hopper, a vertically arranged heating chamber with a circular cross-section, paired with it, on the casing of which a vibrator and discharge chute are mounted on the outside, and electrodes connected to a three-phase AC network are located inside, characterized in that the electrodes are made rectilinear, have a triangular cross-sectional shape, are placed only on the inner electrically insulated surface of the heating chamber body, which you is full, and the sum of the internal angles of the vertices of the electrodes facing the center is 360 ^o , while the adjacent faces of the adjacent electrodes are parallel to each other, the heating chamber is paired with the hopper elasto-tight, and the discharge chute acting as an adjustable shutter is made in the form of a round nozzle , the inner diameter of which corresponds to the inner diameter of the heating chamber, and the lower end is bounded by two planes, symmetrical with respect to the central horizontal axis, inclined to the vertical at an angle of not more than 45 ^o, in which there are movable flap moving on rails attached to the housing unloading chutes, with the possibility of synchronous reciprocation of the actuator, also fixed on the housing unloading chutes.  2. The device according to claim 1, characterized in that plate electrodes are located between the triangular electrodes, and all the electrodes are connected to the phase wires of a three-phase AC network.  3. The device according to claim 2, characterized in that the triangular electrodes are connected to phase wires, and plate electrodes are connected to the zero wire of a three-phase AC network.  4. The device according to p. 2, characterized in that the plate electrodes are connected to phase conductors, and triangular - to the neutral wire of a three-phase AC network.

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