SK286931B6 - Cooling system for cooling at least one rubber strip - Google Patents

Abstract

A cooling system comprising a conveyor device (2) which is used to continuously convey the rubber strip (1), in addition to an air diffusing device enabling cooling air which is conveyed by a blowing device to flow out onto at least one flat side of the rubber strip (1). The air diffusing device is divided into at least one first air cooling unit (3a) and at least one second air cooling unit (3b). The air diffusing device is arranged downstream from the first air cooling unit, and the blowing device is divided into at least one first fan (4a) and at least one second fan (4b). The first fan (4a) provides the first air cooling unit (3a) with non pre-cooled cooling air suctioned from surrounding atmosphere. The second fan (4b) provides the second air cooling unit (3b) with cooling air. The second air cooling unit (3b) is disposed in a substantially closed housing (5), the rubber strip (1) being able to be conveyed there through by the conveyor device (2). The second fan (4b) has an air suctioning pipe (6) arranged inside the housing (5) for guiding the circulation of cooling air. And a heat exchanger (8) which is connected to a cooling unit (7) is provided in order to pre-cool the cooling air which is recirculated in the housing (5).

Description

Technical field

The invention relates to a cooling device for cooling one or more rubber belts with a conveyor device for continuously conveying rubber belts and an air distribution device which allows the cooling air conveyed by the blower to flow to at least one flat side of the rubber belts.

BACKGROUND OF THE INVENTION

Rubber belts are intermediates that are further processed to produce a variety of rubber end products such as tires. Such rubber belts can be manufactured in various ways. They may have a smooth or profiled surface. A conventional rubber belt manufacturing apparatus has an extruder which is equipped with a wide-slot extrusion head to extrude a flat rubber skein. This wide-slot extrusion head transports the material immediately into the roll gap of a rolling machine formed, for example, of two rolls, which rolls the extruded product onto the desired rubber sheet of constant thickness. The rubber strip typically has a mass temperature of approximately 80 to 100 ° C at the exit of the rolling machine. In order to ensure trouble-free further processing of the rubber band, it is necessary to cool the rubber band to about 35-40 ° C. For this purpose, cooling devices are often used today, which operate with air as a cooling medium.

Such air cooling devices essentially consist of a conveyor device for continuously conveying the rubber band, over which is disposed an air distribution device which, by means of a blower, transports cooling air towards the flat side of the rubber band for cooling purposes. The length of the conveyor device must be chosen such that the rubber band is cooled to the desired end temperature at the end of the conveyor device. Alternatively, the cooling air is sucked through the blower from outside or from the work room in which the entire machine is located, and is usually blown over a large number of nozzles onto the surface of the material. It is known that in order not to be too long for the conveyor device and to cool the rubber strip as quickly as possible, the cooling air is cooled to a temperature of, for example, 20 ° C by means of a heat exchanger which is connected to the cooling unit.

In such a method, the cooled air heats up relatively little during its contact with the surface of the rubber band. After cooling, the relatively slightly heated cooling air is mixed with the air in the work hall. The energy used to cool the cooling air is therefore wasted. In addition, the introduced cooling capacity of the cooling unit and the dimensions of the heat exchanger are considerable. This type of cooling of the rubber belts thus generates not only considerable investment costs, but also significant production costs, in particular in the form of energy costs.

It is an object of the present invention to further provide a cooling device of this kind so that the investment and production costs are permanently reduced with the unchanged cooling result.

SUMMARY OF THE INVENTION

This object is achieved by a cooling device for cooling at least one rubber band, with a conveyor device for continuously conveying the rubber band and with an air distribution device allowing the cooling air conveyed by the blower to flow on at least one flat side of the rubber band according to the invention. the air distribution device is divided into at least one first air cooling unit and at least one second air cooling unit downstream of the first air cooling unit, the blower device being divided into at least one first fan and at least one second fan that the first air cooling unit is supplyable by the first ambient air fan, that the second air cooling unit can be supplied by the second air cooling fan, that the second air cooling unit is arranged in a fully enclosed housing which thereby passing the rubber belt through the conveyor device, that the second fan comprises an air intake connection arranged inside the housing for guiding cooling air in the circuit and that a heat exchanger is connected to the cooling unit to pre-cool the cooling air returned to the housing.

Preferred embodiments are set forth in the subclaims.

The present invention utilizes the idea of conducting cooling air precooled at a high power consumption in the circuit to compensate for only the temperature rise in the cooling air produced by

In order to avoid loss of mixing with the ambient air as much as possible. The energy used for this purpose is clearly lower than if it were always necessary to cool new air from the surroundings.

Since the cooling air is substantially free from the air distribution device, it is virtually impossible to recover the cooling air directly to be circulated in the circuit. For such a circuit in the circuit, it is necessary to carry out cooling in a room closed against the environment. Due to the large dimensions of the conveyor equipment, such a confined space would require very high investment costs.

The invention therefore clearly goes beyond the basic ideas described and proposes to reduce the investment costs by precooling only one partial flow of the total cooling air used and circulating it in the circuit. For this purpose, the air distribution device is divided into at least one first and at least one second air cooling unit downstream of the first.

Accordingly, the blower device is also divided into at least one first and at least one second fan, the first air cooling unit being supplied with ambient air from the first fan.

The energy consumption for supplying this cooling air is therefore generally low. Only the at least one second air cooling unit, which is located downstream of the first air cooling unit, is supplied with pre-cooled cooling air from the second fan. In order for this cooling air to be circulated in the circuit, the second air cooling unit is housed in a well-sealed housing through which the rubber belt to be cooled can be guided by a conveyor device. For this purpose, the air intake port of the second fan is located inside the housing. Mixing with ambient air is largely avoided. Therefore, a cooling unit that provides the refrigeration required to cool the cooling air in the circuit by means of a heat exchanger connected to the circuit of the second fan must provide only a relatively low cooling capacity because the temperature difference between freshly supplied cooling air and cooling air drawn from the housing is relatively small .

In order that the cover itself absorbs as little thermal energy from the environment as possible, it is advantageous to provide the cover with appropriate thermal insulation.

Due to the location of the heat exchanger to cool the freshly supplied cooling air, it is recommended that it be located in the return air supply line from the second fan to the housing.

Of course, more than one first or second air cooling unit may be provided in the cooling device. If necessary, these can also be operated at different temperatures of the cooling air, so that a cascading connection of the other air cooling units is also possible. However, it has been found that in most cases only one first and one second air cooling unit are already fully sufficient for this device. Given the length of the conveying path of the conveyor device, it is recommended that the first air cooling unit extends over a partial length of about 55 to 80%, preferably 60 to 70%, and the second air cooling unit over a partial length of 45 to 20%, preferably 40 to 30% the total length of the conveyor device.

It is recommended that air cooling units be equipped with a plurality of air outlet nozzles whose exhaust direction is directed to the surface of the rubber strip to be cooled.

Suitably, the overall production equipment, including the cooling device, is placed inside the work hall and the cooling air for the first air cooling unit is drawn in from inside the work hall. For this purpose, the air intake connection for the first fan is located inside the work hall.

The conveyor device is expediently designed in the form of a circulating conveyor belt which extends through the cover to the second air cooling unit.

BRIEF DESCRIPTION OF THE DRAWINGS

In the following, the present invention is explained in more detail by way of a schematic example of the embodiment shown in Figure 1.

Figure 2 shows a comparative example in which the total cooling air is precooled in a heat exchanger.

DETAILED DESCRIPTION OF THE INVENTION

The rubber belt designated 1 is continuously conveyed from left to right by a horizontally formed conveyor device 2 in the form of a circulating conveyor belt. For example, the total length of the conveyor is 30 m. Above the conveyor device 2 is provided a first air cooling unit 3a, which is supplied by the first fan 4a with non-pre-cooled, ambient air sucked in. The cooling air flows essentially vertically from top to bottom onto the surface of the rubber belt resting on its wider side on the conveyor belt. In this case, the first air cooling unit 3a extends over a length of approximately 20 m. In the transport direction, a second air cooling unit 3b, which is located inside the housing 5 and extends over a length of approximately 10 m along the conveyor device 2, is immediately downstream of the first air cooling unit 3a. 9 for circulating cooling air, the air intake 6 of the circulation pipe 9 is located inside the housing 5. Cooling air drawn from the housing 5 is fed back to the housing 5 towards the surface in a precooled state through the second fan 4b and the heat exchanger 8 downstream thereof. The rubber belt 1 has been manufactured in a manufacturing apparatus which is located on the left side of the conveyor apparatus 2 but is not shown in the figure. This production device consists, for example, of a twin-screw extruder with a wide-slot extrusion head and downstream of a two-roll rolling machine.

The operation of the described cooling apparatus is as follows: From a production apparatus (not shown), the rubber strip 1 having a temperature of about 80 to 100 ° C reaches the region of the first air cooling unit 3a. The first fan 4a draws ambient air from the vicinity of the cooling device in the work hall, for example having a temperature of at most 35 ° C. This ambient air is blown by means of an air cooling unit 3 onto the upper wider side of the rubber belt 1. The temperature difference between the cooling air and the surface of the rubber belt 1 is suitably large, particularly in the inlet region of the conveyor device 2, to effect efficient cooling. Up to the end of the conveying path, the material under the first air cooling unit 3a is cooled, for example, up to about 50 ° C. If cooling was no longer carried out by means of pre-cooled ambient air, the cooling efficiency would be reduced and thus the required cooling path length would be greatly extended. Therefore, in the second section of the cooling device, pre-cooled cooling air is used. For example, it has a temperature of about 10 ° C. This also results in a relatively large temperature difference in the second cooling section, which ensures rapid cooling of the rubber band from about 50 ° C to the desired final temperature of about 35 to 40 ° C. Compared to the first cooling section, the second cooling section with pre-cooled cooling air has a substantially shorter length. A temperature range of about 0 ° C to 20 ° C is suitable for the temperature of the precooling air. The actual cooling air temperature and the desired final temperature are important determining parameters for the required length of the second cooling path.

In the cooling device shown in Figure 2 for comparison with the present invention, the total air used for cooling, which is supplied to the rubber belt 1 via the air distribution device 3, is cooled by a heat exchanger 8 connected to the cooling unit 7. The air distribution device 3 is cooled. the cooling air is drawn in from the surroundings of the device by means of a single fan 4 and the cooled air is directed through the air outlet nozzles of the air distribution device 3 to the flat upper side of the rubber belt 1 and then mixed again with the air around the device .

In comparison with the cooling device according to FIG. 2, in which the total cooling air is pre-cooled, the cooling device according to the invention works considerably more efficiently, i. j. with significantly lower energy costs. Because at a rubber flow rate of 3,500 kg / h, the rubber strip is to be cooled from 90 ° C to 35 ° C, a cooling power of approximately 180 kW is required for the cooling unit to cool the total cooling air from a temperature of approx. 35 ° C obtained in the intake area to a temperature of about 20 ° C in the cooling air outlet area. In this case, the length of the cooling path would be approximately 40 m.

However, when a cooling device according to the invention is used instead, in which precool air is operated at the same flow rate only in the second section of the cooling device, the cooling air is only heated by approximately 2 to 2 between the cooling air outlet and the air intake. Cooling from 50 ° C down to the required 35 ° C to be carried out in the second cooling section corresponds to a temperature difference of only 15 K. Therefore, the cooling unit requires a drive power of only 56 kW at a rubber flow rate of 3,500 kg / h. The total length of the cooling path is approximately 30 m.

As a result, the required length of the cooling device is about 1/3 greater with a conventional cooling device and, moreover, the required investment amount is almost 50% higher than with a cooling device according to the invention. The cooling device according to the invention requires only 1/3 of the driving power for the cooling unit. The energy costs for driving the fans are approximately equal in both cases.

In the cooling device shown in Figure 2 for comparison with the present invention, the total air used for cooling, which is supplied to the rubber belt 1 via the air distribution device 3, is cooled by a heat exchanger 8 connected to the cooling unit 7. The air distribution device 3 is cooled. the cooling air is drawn from the surroundings of the conveyor by means of a single fan 4 and the cooled air is directed

Through the air outlet nozzles of the air distribution device 3 to the flat upper side of the rubber band 1.

Claims (8)

PATENT CLAIMS A cooling device for cooling at least one rubber band (1), having a conveyor device (2) for continuously conveying the rubber band (1) and an air distribution device allowing the cooling air conveyed by the blower to flow on at least one flat side of the rubber band (1). 1), characterized in that the air distribution device is divided into at least one first air cooling unit (3a) and at least one second air cooling unit (3b) downstream of the first air cooling unit (3a), the blower device is divided into at least one first fan (4a) and at least one second fan (4b), that the first air cooling unit (3a) can be supplied by the first fan (4a) with ambient air, the second air cooling unit (3b) is supplied by the second a cooling air fan (4b) that the second air cooling unit (3b) is u arranged in a completely enclosed housing (5) through which the rubber band (1) passes through the conveyor device (2) that the second fan (4b) comprises an air intake nozzle (6) arranged inside the housing (5) for guiding cooling air in the circuit and A heat exchanger (8) is connected to the cooling unit (7) to pre-cool the cooling air returned to the housing (5). Cooling device according to claim 1, characterized in that the cover (5) is provided with thermal insulation. Cooling device according to one of Claims 1 and 2, characterized in that the heat exchanger (8) is arranged in the cooling air duct leading from the second fan (4b) to the housing (5). Cooling device according to one of Claims 1 to 3, characterized in that it comprises only one first air cooling unit (3a) and only one second air cooling unit (3b). Cooling device according to one of Claims 1 to 4, characterized in that the air cooling units (3a, 3b) are provided with air outlet nozzles. Cooling device according to one of Claims 1 to 5, characterized in that the first air cooling unit (3a) is provided with a suction branch located in the work hall for sucking cooling air from inside the work hall. Cooling device according to one of Claims 1 to 6, characterized in that the conveyor device (2) is designed as a circulating conveyor belt. Cooling device according to one of Claims 1 to 7, characterized in that the first air cooling unit (3a) extends over a partial length of 55 to 80%, in particular 60 to 70%, and the second air cooling unit (3b) extends on a partial length of 45 to 20%, in particular 40 to 30%, of the total length of the conveyor device (2).