RU2328683C2 - "виз" plate recuperator - Google Patents

Abstract

FIELD: mechanical engineering; heat recuperation.

SUBSTANCE: closed-circuit counter-current recuperator with intensifiers has alternating channels for two heat-carriers formed by flat metal sheets integrated into a package with alternating intervals equal to heights H1 and H2 of the channels and tightly jointed to each other along the edges on appropriate sites. Appropriate side surfaces of the said package have heat-carriers inlet into the aforesaid channels and outlets thereof. Metal sheets are made in the form of a closed ring and, when assembled into the package, form the inner manifold arranged along the package axis. Inlets and outlets of the first hear carrier are located at equal distances from each other all along the ring on the inner manifold side. The second heat carrier inlets and outlets are located outside the package at equal distances from each other all along the ring.

EFFECT: lower production costs, higher reliability and service life of heat exchangers.

6 cl, 6 dwg

Description

The invention relates to energy, transport and chemical engineering, the food industry and can be used in heat exchangers.

Tubular recuperators are widely known, having channels for the flow of two coolants, formed by metal pipes assembled into a tube bundle and connected by tube boards and a casing, the first coolant flowing inside the pipes and the second coolant flowing in the annulus inside the casing [1]. One of the significant drawbacks of tubular recuperators is the relatively high mass and dimensions. The disadvantage of these recuperators is also the high cost due to the high material consumption and the complexity of manufacturing, which is largely determined by the large amount of metal machining in the manufacture of tube plates.

A plate heat exchanger adopted by us for the prototype is known. It has intermittent channels for the flow of two heat carriers, formed by metal sheets stacked in a packet at alternating intervals equal to the heights H1 and H2 of the channels and tightly connected to each other at the edges at the corresponding sections, while on the corresponding side the surfaces of the package have inputs and outputs of coolants into the said channels [2]. It has better mass-dimensional characteristics than tubular recuperators. The absence of tube plates reduces the complexity of its manufacture. However, the large total length of the tight joints of the sheets with each other complicates the design of the recuperator. Therefore, the complexity of its manufacture and cost remain quite high. In addition, under the conditions of a non-uniform asymmetric temperature field characteristic of such recuperators, it is difficult to ensure the density of the joints of sheets with each other during long-term operation, which reduces the reliability and life of the recuperator. The need for uniform distribution of coolant through the channels requires the presence of input and output collectors of appropriate sizes, which increases the mass and dimensions of the recuperator.

The task to which the invention is directed is to simplify the design and reduce the material consumption and the complexity of manufacturing a recuperator.

The problem is solved by the implementation of a plate VIZ recuperator (Interval with Intensifiers Closed), which have intermittent channels for the flow of two coolants, formed by flat metal sheets stacked in a packet with alternating intervals equal to the heights H1 and H2 of the channels and tightly connected to each other at the edges corresponding sections, while on the corresponding side surfaces of the package there are inputs and outputs of the coolant in the said channels, in which the metal sheets are made in the form of a closed ring and, when typed into a packet, form an internal collector located along the axis of the packet, while the inputs and outputs to the channels for the flow of the first coolant are located on the side of the internal collector at equal distances from each other along the ring, and the inputs and outputs to the channels for the flow of the second coolant are located on the outer side of the package at equal distances along the ring from each other.

Moreover, in some cases, the windows for the entrance of the first coolant are located opposite the windows for the exit of the second coolant, and the windows for the exit of the first coolant are located opposite the windows for the entrance of the second coolant.

Moreover, in some cases, the sheets forming a channel for the flow of at least one coolant are made with ribbing.

Moreover, in some cases, the option of a plate VIZ recuperator is also possible, when the distance between the ribs is made variable.

Moreover, in some cases, the sheets forming a channel for the flow of at least one coolant are made with surface irregularities of a given height arranged in a certain way.

Moreover, in some cases, the option of a plate VIZ recuperator is also possible when the step of arranging irregularities of a given height on the surface of the sheets is made variable.

The technical result achieved by the implementation of the inventive device is to reduce the manufacturing cost, increase the reliability and resource of the recuperator.

The specified technical result is achieved due to the fact that the metal sheets are made in the form of a closed ring and when typed into a packet form an internal collector located along the axis of the packet, while the inputs and outputs to the channels for the flow of the first coolant are located on the side of the internal collector at equal distances along the ring from each other, and the inputs and outputs of the channels for the flow of the second coolant are located on the outside of the package at equal distances along the ring from each other. The execution of metal sheets in the form of a closed ring can significantly reduce, compared with the prototype, the total length of the tight joints of the sheets at the edges, since instead of four side faces, the VIZ recuperator package has only two side surfaces covering the inner and outer perimeters of the annular sheets.

The total length of the tight joints of the sheets along the edges can also be reduced by the fact that the entrances and exits to the channels for the flow of the first coolant are located on the side of the internal collector, while the entrances and exits to the channels for the flow of the second coolant are located on the outside of the package. This eliminates the need for walls of complex shape separating the coolant in the areas of entry and exit of the recuperator, as is the case in the prototype. Since these dividing walls are, as a rule, at a sufficiently high pressure equal to the pressure difference of the coolants, their exclusion from the design of the heat exchanger not only reduces the manufacturing complexity and cost, but also increases the reliability and service life of the heat exchanger.

Due to the fact that the inlet and outlet sections of the first coolant are separated by an annular package from the inlet and outlet sections of the second coolant, there is no need to tightly connect the edges of the sheets in the sections from the inlet to the outlet of each coolant. This allows you to simply close the inner and outer side surfaces of the annular package adjacent to the edges of the sheets of the walls, in which there are corresponding windows for the entry and exit of coolants in the channels. In this case, a high density of the walls against the edges of the sheets is not required, since the pressure drop between the inlet and outlet of one coolant is usually relatively small and, accordingly, possible overflows due to leaks. It also greatly simplifies the design of the recuperator, reduces its cost, increases reliability and increases the resource.

A significant reduction in the cost of the recuperator, an increase in its reliability and resource is also achieved by the fact that the metal sheets are made in the form of a closed ring and, when typed into a packet, form an internal collector located along the axis of the packet, while the entrances and exits to the channels for the flow of the first coolant are located on the side internal collector. Thus, the need for external input and output collectors for the first coolant disappears. This advantage is especially noticeable when a high pressure coolant is considered as the first heat transfer medium. The location of the inputs and outputs into the channels for the flow of each of the coolants at equal distances along the ring from each other provides an equal length of channels between the respective inputs and outputs of the coolants, which is obviously necessary for uniform distribution of coolants through all channels, ensuring maximum thermal efficiency of the heat exchanger, high reliability and resource.

The indicated technical result is achieved by the implementation of a plate VIZ recuperator, in which the windows for the inlet of the first coolant are located opposite the windows for the outlet of the second coolant, and the windows for the exit of the first coolant are located opposite the windows for the inlet of the second coolant, which implements a countercurrent flow pattern of the coolants at which the heat efficiency of the heat exchanger is maximized . Increasing the heat efficiency of the heat exchanger allows you to reduce the heat transfer surface and, therefore, the material consumption of the heat exchanger. Thus, with increasing thermal efficiency, a technical result is achieved - reducing the cost of manufacturing a heat exchanger.

The specified technical result is achieved in another embodiment of a plate VIZ recuperator, which provides for the execution of sheets forming a channel for the flow of at least one coolant with fins. It is known that surface finning allows in many cases to increase the heat transfer intensity, which, as mentioned above, reduces the cost of manufacturing a heat exchanger. In addition, with a significant difference in the pressures of the coolants, the implementation of ribbing inside the channel with low pressure provides structural strength and allows the use of metal sheets of smaller thickness, which also achieves the specified technical result.

Similarly, the intensification of heat transfer and providing additional strength to the design of the heat exchanger with the achievement of the specified technical result is ensured in the embodiment of the plate VIZ heat exchanger, which provides for the sheets forming the channel for the flow of at least one coolant with surface irregularities of a given height located in a certain way.

The indicated technical result is also achieved in a possible embodiment of a plate VIZ recuperator, in which the step of arranging irregularities of a given height on the surface of metal sheets is made variable along the width and / or length of the tape. Obviously, the length of the coolant flow lines from the input window to the output window differs depending on the location of the start point of the flow line in the input window. This leads to the corresponding unevenness of the velocity and temperature fields of the coolant. By appropriately changing the pitch of the irregularities, it is possible to increase the uniformity of the distribution of velocities and temperatures of the heat carriers along the heat exchange surface and thereby increase the thermal efficiency of the heat exchanger. Modern methods of numerical and physical modeling of flows make it possible to determine the optimal law for changing the pitch of irregularities.

The indicated technical result is also achieved in a possible embodiment of a plate VIZ recuperator, in which the distance between the ribs on the surface of the sheets is made variable. As in the previous embodiment of the recuperator, this ensures uniform distribution of the coolant along the channels with a similar result.

The essence of the invention is illustrated by the drawings of figure 1, figure 2, figure 3, figure 4, figure 5 and figure 6. The drawings schematically depict: figure 1 shows a General view of a plate heat exchanger recuperator; figure 2 is a longitudinal section of a plate heat exchanger recuperator; figure 3 is an enlarged fragment of a longitudinal section of a plate heat exchanger recuperator; figure 4 - shows a diagram of the fins of the channel recuperator plate VIZ; figure 5 is an enlarged fragment of the channels of the recuperator plate VIZ, formed by metal sheets with fins; figure 6 is an enlarged fragment of the channels of the recuperator plate VIZ. formed by metal sheets with spherical stampings.

The essence of the proposed device is as follows. The plate-type VIZ recuperator has intermittent channels 1 and 2 (FIG. 3) for the flow of two coolants formed by flat metal sheets 3 and 4, stacked in a packet 5 (FIG. 1 and FIG. 2) with intermittent intervals equal to the heights H1 and H2 of the channels and tightly connected to each other at the edges of the respective sections 6. The metal sheets are made in the form of a closed ring (figure 1 and figure 4) and when typing in the package form an internal collector 7 located along the axis of the package, in which there is a partition 8. In this case, the entrances and exits to the channels for those The first heat carrier flows are located from the side of the internal collector at equal distances along the ring from each other, and the entrances and exits to the channels for the second heat carrier flow are located on the outside of the package at equal distances along the ring from each other.

In the embodiment of the plate-type VIZ recuperator shown in Fig. 1, windows 9 for entering and exiting coolants into the channels are made in walls 10 and 11 adjacent to the edges of the sheets, covering the inner and outer side surfaces of the annular package.

In the embodiment of the plate-type VIZ recuperator shown in Fig. 1, the windows for the inlet of the first coolant are located opposite the windows for the exit of the second coolant, and the windows for the exit of the first coolant are located opposite the windows for the entrance of the second coolant. It should be noted that by the number and location of the inlet and outlet windows of the coolant, the designs of the recuperator can be very diverse: the number of inlet and outlet windows for each of the coolants can be, theoretically, any, and their relative location determines the thermal circuit (counterflow, direct flow, mixed circuit ) plate-type VIZ recuperator. The choice of the number and location of the input and output windows of the coolant depends on the specific operating conditions of the plate VIZ recuperator and is carried out during its design.

An embodiment of a plate VIZ recuperator is possible, in which the sheets forming a channel for the flow of at least one coolant are made with fins 12 (Fig. 4 and Fig. 5). As can be seen from figure 3, the metal sheets in the form of a closed ring can be made, for example, in the form of a regular polygon.

An embodiment of a plate VIZ recuperator is possible, in which the sheets forming a channel for the flow of at least one coolant are made with surface irregularities of a given height arranged in a certain way. In particular, in FIG. 5, irregularities of a given height on the surface of metal sheets are made in the form of convex spherical stampings 13 and 14, the heights of which are equal to the heights of the channels H1 and H2 for the flow of coolants.

The work of the plate-type VIZ recuperator is as follows. The first coolant is supplied to the channels 1 (Fig. 1, Fig. 2 and Fig. 3) from the collector 7 through the inlet window in the wall 10 and, being divided into two flows, moves along these channels in the direction of the outlet window in the same wall (direction of movement heat carriers are shown in the drawings by arrows), where two flows merge again into one and leave the recuperator along collector 7. On the outside of the package 5 there are similar windows of the second coolant. The motion scheme of the second coolant in the channels 2 is completely similar to the motion scheme of the first, with the only difference being that it is supplied and removed from the outside of the package. Flowing through channels 1 and 2, coolants wash the walls separating them - metal sheets 3 and 4. Since the temperature of the coolants on both sides of the walls is different, heat exchange occurs between them. Irregularities 13 and 14 located in a certain way on the walls, as well as ribbing of the walls 12 intensify the heat transfer process in channels 1 and 2.

The possibility of implementing the inventive plate-type VIZ recuperator is not in doubt, since widely known materials (sheet steel, rolled metal tape, etc.) and technological processes (stamping, welding, etc.) can be used for this.

INFORMATION SOURCES

1. Bazhan P.I. et al., Handbook of heat exchangers, M .: Engineering, 1989.

2. A.S. USSR No. 1829559, Plate heat exchanger, IPC F28F 3/08, F28D 9/00, publ. 20/02/1996.

Claims (6)

1. The plate-type VIZ recuperator (closed-loop with intensifiers closed), having intermittent channels for the flow of two coolants, formed by flat metal sheets stacked in a packet with alternating intervals equal to the heights H1 and H2 of the channels and tightly connected to each other along the edges in the corresponding sections, while on the respective side surfaces of the package there are inputs and outputs of the coolant in the said channels, characterized in that the metal sheets are made in the form of a closed ring when entering into a bag, an internal collector is located, located along the axis of the bag, while the inputs and outputs to the channels for the flow of the first coolant are located on the side of the internal collector at equal distances along the ring from each other, and the inputs and outputs to the channels for the flow of the second coolant are the outer side of the package at equal distances along the ring from each other. 2. The VIZ recuperator according to claim 1, characterized in that the windows for the inlet of the first coolant are located opposite the windows for the exit of the second coolant, and the windows for the exit of the first coolant are located opposite the windows for the entrance of the second coolant. 3. The plate-type VIZ recuperator according to claim 1, characterized in that the sheets forming a channel for the flow of at least one coolant are made with ribbing. 4. The plate-type VIZ recuperator according to claim 3, characterized in that the distance between the ribs is made variable. 5. The plate-type VIZ recuperator according to claim 1, characterized in that the sheets forming a channel for the flow of at least one coolant are made with surface irregularities of a given height arranged in a specific way. 6. The plate-type VIZ recuperator according to claim 5, characterized in that the step of arranging irregularities of a given height on the surface of the sheets is made variable.

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