SU1712762A1 - Heat exchanger - Google Patents

Abstract

The invention relates to heat exchangers used to exchange thermal energy between a liquid and a gas or air, more specifically to radiators of vehicles and stationary installations, and can be used in power and transport engineering industries. The purpose of the invention is to increase the intensification of heat transfer. The heat exchanger contains bundles (P) 1 and 2 of vertical pipes 3, equipped with common fins in the form of plates 4. Pipes 3 P 1 and 2 are installed in tube plates 5 attached to collectors 6. Plates 4 form flat channels (K) 7 and 8 constant lengthwise cross section. In this case, the plates 4 in each P 1 and 2 are arranged with a variable pitch of quince alternating along the length of the pipes 3, and the ratio of transverse adjacent K 7 and 8 in each P 1 and 2 is 1: 3, and K 8 of a smaller section are coaxially K 7 larger sections of the other beam, which allows the air stream coming out of P 1 to be broken up into small streams by plates interacting with each other in front of the front of the subsequent beams and thus achieve the destruction of the boundary layer in K 7 and 8. 2 ill. Yu

Description

The invention relates to heat exchangers used for the exchange of thermal energy between a liquid and a gas or air, more specifically to radiators of vehicles and stationary installations, and can be used in power and transport engineering industries.

A heat exchanger is known, which comprises bundles of vertical tubes provided with common fins in the form of plates forming flat channels of constant cross-section along the length,

Due to the fact that the adjacent plates form flat channels of constant cross section, the air flow, passing through the channels of each bundle of vertical pipes, does not meet on its way the destruction of the jet core to the elementary jets at the flow entrance to the subsequent bundles of tubes. In this connection, the destruction of the boundary layer in these channels is not reached, which generally reduces the turbulization of the air flow, and, as a result, leads to a decrease in the intensification of heat transfer.

Also known is a heat exchanger containing sections assembled from two identical bundles of vertical tubes, provided with common fins in the form of plates with the same pitch, forming flat channels of constant cross-section along the length.

Since the sections are made of two identical bundles of vertical tubes, equipped with common finning in the form of plates with the same pitch, forming flat channels of constant cross section along the length, this circumstance makes it impossible to propagate the effect of high heat transfer before the front of subsequent bundles pipes, as well as the depth of their channels, since the air flow, the passage through the channels of each beam, does not meet on its way the destruction of the boundary layer in these channels, which generally reduces the air turbulization flow, and, consequently, leads to a decrease in the intensification of heat transfer.

The closest to the technical essence and the achieved result to the proposed solution is a heat exchanger containing bundles of vertical tubes equipped with common fins in the form of plates that form flat channels of constant cross-section along the length

An additional corrugated mesh is placed in this heat exchanger between bundles of vertical pipes, which reduces the flow area of the channels before the air flow enters the subsequent channels of the second tube bundle, which leads to an increase in aerodynamic drag by 15–17%, a decrease in mass

the velocity of the air drawn through the subsequent bundles of pipes, and thus the decrease in the Reynolds number is proportional to the velocity of the air, which leads to a decrease in the flow turbulization

0 and, as a result, reduces the heat transfer coefficient by 8 - 10%. On the other hand, in such a heat exchanger, with a constant supply of power to the motor-fan, the flow of air drawn through is reduced.

5 through tube bundles, and in order to increase the intensity of the heat exchanger, it is necessary to increase the power of the motor-fans in proportion to the value of its aerodynamic resistance (corrugated

0 grid). In addition, in this heat exchanger jets of air flow when passing through the channels along the depth of the tube bundle do not destroy the boundary layer in the channels. This circumstance also reduces turbulence.

5 air flow in the channels and leads in general to a decrease in the intensification of heat transfer.

The purpose of the invention is to increase the intensification of heat transfer.

0The goal is achieved by the fact that

heat exchanger consisting of tube bundles, equipped with fins in the form of plates, forming flat channels of constant cross section along the length,

5 each beam are arranged in variable pitch alternating with the length of the pipes, and the ratio of the cross sections of adjacent channels in the beam is 1: 3, with the channels of a smaller section being coaxial to the channels of a larger section of the other beam.

Due to the fact that the plates in each bundle are arranged with variable pitch alternating along the length of the tubes, and the ratio of the cross sections of adjacent channels in

5, the beam is 1: 3, while the channels of a smaller section are located coaxially with the channels of a larger section of the other beam; at the entrance to the next bundle of vertical pipes, the air flow is divided by plates into

0 small streams and its flow through the channels is accompanied by the following process. Thus, when a stream of a smaller cross-section of the first along the air of the tube bundle flows out, the flow enters the channel of a larger

5 sections of the next bundle of pipes along its central part, and along its peripheral part flows from the channels of a larger section, covering the channel of a smaller section along the air flow of the pipe bundle. In this connection, the boundary layer is destroyed in the channel of a larger cross section of the next tube bundle, which causes additional turbulization in its channel due to the interaction of the central and peripheral flows, which contributes to an increase in the thermal efficiency of the heat exchanger and leads to an intensification of heat exchange.

When a stream from an adjacent channel of a larger cross section flows down the air of the tube bundle, a part of the flow enters the channel of a smaller cross section of the next tube bundle, and the other part of it is directed to a channel of a larger cross section that covers the smaller section of the next tube bundle. In this connection, the flow of air into the channel into both the larger and smaller sections of the next tube bundle causes the destruction of the boundary layer in the channels due to the interaction of these flows. This contributes to an increase in the turbulence of the air flow in adjacent channels and leads to the intensification of heat transfer in general.

Due to the fact that the channels of smaller section are coaxially arranged with a ratio of sizes in cross section equal to 1: 3, and their outlet and inlet edges in the corresponding channels of the tube bundle are opposite to each other, when the outflow of the air from the channels of the first bundle passes through the air In the coaxial channels of the subsequent tube bundle, equalization of air flow rates and velocities over the entire cross section of the channels is achieved, which promotes a decrease in aerodynamic drag.

So, when air flows out of a smaller channel section opposite the channel of a larger section of another tube bundle, 1/3 of the air flow flows along the axis of the latter, and 1/3 of the air flow from the larger channels flows through the periphery of its channel. sections covering the specified channel of a smaller section.

When the air flow from the larger section channel opposite the smaller section channel and a part of the larger section section of another tube bundle, 1/3 of the air flow flows along the axis of the larger section covering the specified smaller section channel , flows in 1/3 of the air flow. This circumstance leads to the fact that the depth and height of subsequent beams ensure uniform destruction of the boundary layer in each channel, which in general

rationally contributes to the intensification of heat transfer.

When the ratio of the cross sections of the channels changes in the direction of their increase or decrease, the optimal characteristics of the heat exchanger decrease, since the change in the cross sections of the channels creates, first of all, uneven distribution of air flow through the channels, which causes uneven splitting of air flow by the plates, which in general reduces the thermal efficiency of the heat exchanger and leads to a decrease in the efficiency of heat exchange intensification.

So, for example, when the ratio of the cross sections of the channels is 1: 2, air flow rates and velocities over the cross section of the channels are not equalized, since when the air flow from the larger cross section channel opposite the smaller cross section of the other pipe bundle flows out, the latter flows along its axis 1 / 2 part of the air flow, and along the periphery of the channels of a larger section, covering the specified channel of a smaller section, 1/4 part of the air flow flows in. When a stream flows from a smaller section of the channel located opposite the larger section of another tube bundle, the last ½ part of the air flow flows along the axis, and 1/4 part of the air flow from the larger sections covering the specified channel of smaller section.

This leads to the fact that the depth and height of the subsequent tube bundle does not ensure uniform destruction of the boundary layer in each of its channels. This generally reduces the intensification of heat transfer.

When the ratio of the cross section of the channels is 1: 4, the flow rates and velocities over the cross section of the channels are also not equalized, since when the air flow from the larger channel that is opposite to the smaller section of the other tube bundle, the 1/4 part of the air flow flows into the latter , and on the periphery of the channels of a larger section, covering the indicated channel of a smaller section, flows in 3/8 of the air flow. When the flow of air from the adjacent channel of a smaller section, located opposite the channel of a larger section of the other beam, into the last part of the air flow flows in its axis 1/4, and through the periphery of its channel flows 3/8 of the flow of air from the channels of a larger section.

covering the specified channel of smaller section. This also leads to the fact that the depth and height of the subsequent beam does not ensure uniform destruction of the boundary layer in each of its channels, which generally reduces the intensification of heat transfer.

Thus, due to the ratio of the cross sections of adjacent channels in a 1: 3 bundle and the described arrangement of channels of larger and smaller sections in bundles, the subsequent bundles provide a uniform redistribution of flow rates across all channels both in height and depth of the beam. This allows you to simultaneously maintain the same flow rate of the air flow both at the inlet and at the exit from the subsequent tube bundles due to the constant cross section of the channels themselves, which, in turn, reduces the aerodynamic resistance to the air flow.

In general, the separation of the air flow in the channels at the entrance to the second tube bundle into three parts (at a ratio of cross sections of 1/3) leads to the destruction of the boundary layer of air along the entire length of the channel. This is facilitated by the fact that when air flows into the second tube bundle in channels, for example, of a larger cross section, three air drafts are formed at the same time as the flow of air beyond the outlet edge of the first beam channels. One of them is located along the axis of the channel, and the other two encompassing the middle core of the jet, which contributes to the intensive interaction of the cores themselves between C0 (the battle, the intensive interaction of these flows between themselves along the length of the channels and the intense vortex formation of the flows directly along all the walls of the channels). increases the intensification of heat transfer.

A comparative analysis with the prototype shows that the proposed device is different in that the plates in each bundle are arranged with variable pitch alternating along the length of the tubes, and the ratio of the cross sections of adjacent channels in the bundle is 1: 3, and the smaller sections are coaxial with the larger sections another beam.

Figure 1 shows the heat exchanger, the overall appearance; FIG. 2 shows the node I in FIG. 1, the arrangement of the plates in bundles of pipes.

The heat exchanger contains bundles 1 and 2 of vertical pipes 3, equipped with a common orient in the form of plates 4.

The pipes 3 of the beams 1 and 2 are installed in tube plates 5 fastened to the collectors 6. The plates 4 form flat channels 7 and 8 of constant cross-section along the length. Here, the plates 4 in each bundle 1 and 2 are arranged with variable pitch a and b alternating along the length of the tubes 3, and the ratio of the cross sections of adjacent channels 7 and 8 in the bundle is 1: 3. In this case, the channels 8 of a smaller cross section are located coaxially with the channels 7 of a larger cross section of the other beam.

The heat exchanger operates as follows.

The cooled water is directed through the collector 6 into the pipes 3, mounted into the tube sheets 5 of beams 1 and 2, and out through the collector 6 located at opposite ends of the beams 1 and 2 (Fig. 1). Cooling atmospheric air passes through air channels 7 and 8, formed by pipes 3 and adjacent pair plates 4, installed in each bundle 1 and 2 with alternating widths a and b (Fig. 2). Having passed the first beam 1, the cooling air flow enters the second beam 2, where the air flow at the inlet is broken by the plates 4 into small trickles and thus the boundary layer in the channels 7 and 8 is destroyed, which intensifies the heat exchange in the second beam 2.

Technical and economic advantages of the proposed heat exchanger are expressed in increasing the intensification of heat exchange due to the additional forced turbulization of the air flow at the inlet to the second beam 2 without a significant increase in aerodynamic drag.

Claims (1)

Invention Formula A heat exchanger containing bundles of vertical tubes provided with common fins in the form of plates forming flat channels of constant lengthwise cross section, characterized in that, in order to intensify heat exchange, the plates in each bundle are arranged with variable pitch alternating along the length of the tubes, and the ratio the cross sections of the adjacent channels in the beam are 1: 3, and the channels of a smaller section are located coaxially with the channels of a larger section of the other beam. Phi7..2