DE102013102879A1 - Compressor and method for operating a compressor - Google Patents

Abstract

The present invention relates to a compressor with which at least one uncompressed gas sucked in with a suction device of the compressor and entering the compressor can be compressed into a compressed gas emerging from the compressor with the generation of waste heat, with at least one discharge device for at least partial discharge being on the compressor the waste heat from the compressor is provided. The invention further relates to a method for operating a compressor, in which at least one uncompressed gas is sucked into the compressor with a suction device of the compressor and is compressed into a compressed gas emerging from the compressor with the generation of waste heat, the waste heat of the compressor being at least partially over at least one discharge device of the compressor is discharged. It is the object of the present invention to provide a compressor and a method for operating a compressor of the type mentioned above, with which the waste heat of a compressor can be used effectively and directly for heating, for example of buildings. The object is achieved on the device side by a compressor of the type mentioned above, in which at least one gas inlet heat exchanger is provided in or on the intake device, which is coupled to the discharge device for heating the uncompressed gas drawn in by at least part of the waste heat of the compressor, the gas inlet heat exchanger is coupled to a temperature control and / or regulating unit for controlling and / or regulating a thermal output introduced into the uncompressed gas. The task is also solved by a corresponding method.

Description

The present invention relates to a compressor with which at least one sucked with a suction device of the compressor and entering the compressor uncompressed gas is compressible into a discharged from the compressor compressed gas to produce waste heat, wherein at least one discharge device for at least partial discharge to the compressor the waste heat of the compressor is provided. The invention further relates to a method for operating a compressor in which at least one uncompressed gas is sucked with a suction device of the compressor in the compressor and compressed in a discharged from the compressor compressed gas to generate waste heat, wherein the waste heat of the compressor at least partially over at least one discharge device of the compressor is derived.

As is known, compressors have a relatively low efficiency, since a large part of the energy converted by compressors is converted into waste heat.

From the prior art it is known to use the waste heat of a compressor, for example, for heating purposes. For example, in the document DE 40 00 997 C2 describes a working with an air compressor heater, in which the heat generated in the compressed air generation heat is made available for heating purposes. Furthermore, it is known from the prior art, for example the publication DE 30 00 044 A1 , known to provide at various elements of a compressor heat exchanger through which the waste heat of the compressor can be suitably dissipated and subsequently used.

Although a relatively large amount of waste heat is lost during the operation of a compressor, the temperature of the falling heat is usually not high enough to be able to supply radiators or a hot water supply to a building adequately. For example, the waste heat of a conventional compressor has a temperature of at most 42 ° C, for the heating or hot water supply of a building at least 65 ° C to flow temperature required. As a result, it has always been necessary in the prior art to couple the compressor waste heat with a further heat supply in order to be able to use it appropriately for building heating purposes, for example.

In conventional compressors, typically, the incoming gas drawn into the compressor is ambient air drawn in from the outside. In particular, in cold periods, this intake air can be so cold that the achievable by the compressor temperature level is much too low to provide a suitable heat output can. There is even a risk that the compressor freezes.

It is therefore the object of the present invention to provide a compressor and a method for operating a compressor of the above type, with which the waste heat of a compressor can be used effectively and directly for heating, for example, buildings.

The object is achieved on the device side by a compressor of the abovementioned type, in which at least one gas inlet heat exchanger is provided in or on the intake device, which is coupled to the discharge device for heating the sucked uncompressed gas through at least part of the waste heat of the compressor, wherein the gas inlet heat exchanger is coupled to a temperature control and / or regulating unit for controlling and / or regulating a heat output introduced into the uncompressed gas.

In the present invention, at least a portion of the waste heat of the compressor is utilized to raise the temperature level of the compressor. In this case, there is an increase in the gas inlet temperature in the compressor. Due to the increased gas inlet temperature, the operating temperature increases and, consequently, the final compression or outlet temperature of the compressor. By the temperature control and / or regulating unit can be increased by the use of the waste heat of the compressor, the gas inlet temperature of the uncompressed gas in the compressor until the output temperature of the exiting the compressor compressed gas is in a usable range for heating purposes. The operating temperature of the compressor is thus raised according to the invention to a controllable thermal level, so that the compressed gas from the compressor has a temperature level, which can be used below, for example, to supply heaters or hot water supplies, without the absolute need for additional heating.

For example, with the present invention, the operating temperature of the compressor and the temperature of the compressed gas may be adjusted so that the waste heat of the compressor is high enough to allow the recompressed gas introduced into the compressor to be heated to a gas inlet temperature of about 30 ° C.

The compressor according to the invention also has the advantage that the waste heat of the Compressor, especially in cold periods sets the uncompressed gas to an increased gas inlet temperature, which, for example, a freeze of the compressor can be avoided.

In an advantageous embodiment of the present invention, the gas inlet heat exchanger on a gas-gas heat exchanger, wherein in the gas-gas heat exchanger, a heat exchange between the sucked uncompressed gas and the exiting compressed gas is provided. In this embodiment, the hot, compressed gas exiting the compressor is used directly to preheat the uncompressed gas entering the compressor.

In a further variant of the compressor according to the invention, the gas inlet heat exchanger instead of or in addition to the gas-gas heat exchanger to a liquid-gas heat exchanger, wherein in the liquid-gas heat exchanger, a heat exchange between the sucked uncompressed gas and a in a liquid cooling circuit or an oil circuit provided the compressor fluid is provided. In this variant, the waste heat removed by the liquid cooling circuit or the oil circuit of the compressor from the compressor is used to heat the uncompressed gas sucked by the compressor.

It is particularly advantageous if at least one temperature sensor for the measurement of a gas inlet temperature of the uncompressed gas and / or a gas outlet temperature of the compressed gas and / or a pressure sensor for an immediate and / or an ammeter for an indirect determination of a pressure of the compressed gas is provided, and the temperature sensor and / or the pressure sensor and / or the ammeter is coupled to the temperature control and / or regulating unit. By the at least one temperature sensor and / or the pressure sensor and / or the ammeter, the inlet and outlet properties of the compressed gas from the compressor are accurately detected. These properties may be utilized by the temperature control and / or regulation unit to control and / or control the gas inlet temperature of the uncompressed gas by controlling and / or controlling the supply of waste heat from the compressor to the gas inlet heat exchanger. The gas inlet temperature is preferably increased until the gas outlet temperature of the compressed gas is so high that it can be used for heating purposes, if possible without additional heating. The control of the gas outlet temperature can be indirectly used to control the operating temperature of the compressor, for example, certain maximum temperatures must not be exceeded. By the pressure sensor or the ammeter, the pressure of the compressed gas can be detected, which must not exceed certain maximum values. However, in an advantageous embodiment of the present invention, its operating temperature is continuously monitored in order to prevent overheating of the compressor.

The compressor preferably has an intake gas flow divider which can be controlled and / or regulated by the temperature control and / or regulating unit and is present in a feed line of the uncompressed gas, wherein the uncompressed gas passes through the gas inlet heat exchanger and / or past the gas inlet heat exchanger by means of the intake gas flow divider leading detour channel is conductive. By this construction, the amount of the uncompressed gas which is fed into the compressor can be accurately adjusted by means of the suction gas flow divider. As a result, the temperature at which the uncompressed gas leaves the gas inlet heat exchanger and enters the compressor for compression is also determined in connection with the heat output introduced into the gas inlet heat exchanger. The uncompressed gas can also be introduced directly into the compressor via the bypass channel leading past the gas inlet heat exchanger, that is to say without being heated by the gas inlet heat exchanger. Furthermore, it is possible that the uncompressed gas is discharged via the bypass channel away from the compressor, for example to the outside. In a further variant of the present invention, the bypass channel may also include means for external preheating of the uncompressed gas.

In an advantageous embodiment of the compressor according to the invention, the compressor has a controllable and / or controllable by the temperature control Abführgasströmungsteiler in a discharge of the compressed gas, wherein by means of the Abführgasströmungsteilers a gas volume flow of the compressed gas through the gas inlet heat exchanger and / or a not leading through the gas inlet heat exchanger compressed gas channel for controlling and / or regulating a gas inlet temperature of the uncompressed gas in the compressor and / or a working temperature of the compressor is conductive. The purge gas flow divider may define the amount of compressed gas that is provided to the gas entry heat exchanger for preheating the incoming uncompressed gas. This amount of compressed gas according to the invention, depending on the respective required heat output of the compressor for operating a heater or a Hot water treatment determined. The remaining, unused portion of the compressed gas can be supplied via the compressed gas channel directly to a consumer. However, the compressed gas may also pass a dehumidifier before being supplied to the consumer. Furthermore, it is advantageous if the compressed gas channel is coupled to a pressure accumulator, from which a supply of the consumer takes place with compressed air.

It has also proven to be advantageous if the compressor has a controllable and / or controllable by the temperature control fluid flow divider, wherein the fluid flow divider by a fluid volume flow through the gas inlet heat exchanger and / or by a non-passing through the gas inlet heat exchanger Fluidableitkanal for controlling and / or regulating a gas inlet temperature of the uncompressed gas into the compressor and / or a working temperature of the compressor can be conducted. By adjusting the fluid flow divider, which is flowed through by a coming from a liquid cooling circuit and / or an oil circuit of the compressor, warm fluid, the heat output, which is coupled into the uncompressed gas in the gas inlet heat exchanger, can be determined. If, for example, a desired value for the gas inlet temperature has already been reached, the heat exchange between the warm fluid and the uncompressed gas entering the compressor can be prevented by the fluid flow divider. On the other hand, when the uncompressed gas is very cold, the fluid flow divider may be fully opened so that all the fluid is available for heating the uncompressed gas.

In a further exemplary embodiment of the present invention, the compressor has a speed control module which can be controlled and / or regulated by the temperature control and / or regulation unit and serves to control the speed of a drive motor of the compressor. Thus, by the compressor speed of the flow or the amount of gas exiting the compressor, compressed and thus warm gas can be adjusted to allow, for example, a rapid heating of entering the compressor, uncompressed gas by the exiting gas.

According to a further optional embodiment of the compressor according to the invention this has a throttle valve in a discharge of the compressed gas. The throttle valve serves to narrow the flow area in the area of the compressed gas, thereby increasing the compression work to be performed by the compressor and the pushing operation of the compressor, respectively. This can shorten the heating time of the compressor.

The object is further achieved by a method for operating a compressor according to the above-mentioned type, wherein the sucked uncompressed gas is heated by a part of the waste heat of the compressor in at least one provided in or on the suction gas inlet heat exchanger by heat through the discharge device and the Gas inlet heat exchanger is passed into the sucked uncompressed gas, wherein a temperature control and / or regulating unit controls a introduced into the uncompressed gas heat output and / or regulated.

With the method according to the invention, the waste heat of the compressor is used effectively. This waste heat of the compressor is transmitted to the entering into the compressor uncompressed gas, so the intake air of the compressor tempered. In this way, with no or little external energy input, the process energy level of the compressor and thus the temperature of the compressed gas from the compressor is raised so that the temperature of the compressed gas leaving the compressor can be further utilized, that is, for direct heating, for example ,

In the method according to the invention, the sucked uncompressed gas is heated only as long as necessary. If it is determined by the temperature control and / or regulating unit that the uncompressed gas already has a suitable temperature, the further initiation of heat output into the uncompressed gas is prevented by the temperature control and / or regulating unit. In this way, the compressor is operated at a relatively high operating temperature, which is adjustable by the temperature control and / or regulating unit so that it is high, but below the maximum operating temperatures of the compressor. As a result, the gas outlet temperature from the compressor in comparison to conventional compressors is significantly higher and therefore much easier for heating purposes, for example, for heating buildings, used. The gas outlet temperature of the compressor, for example, can be set so high that an additional heating is not necessary and the energy of the hot, compressed gas, which has a high temperature level, is transferred to a heat exchanger, which in turn for heating radiators or for supplying hot water supply systems for buildings can be used.

Since the own waste heat of the compressor is used to operate the gas inlet heat exchanger, almost a self-sufficient system, which self-adjusts itself to a preset operating point by the temperature control and / or regulation unit. The operating point is specified by a consumer-side system, such as a hot water treatment plant or a machine to be tempered, which has a heat demand. For example, a water supply temperature of 85 ° C at a water supply speed of 50 l / min can be specified by a hot water treatment plant. The temperature control and / or regulating unit then adjusts this operating point by means of the system components according to the invention described above. In this case, an overheating protection is preferably provided on the compressor, which monitors the maintenance of the operating temperature of the compressor and reduces the temperature increase of the uncompressed gas supplied to the compressor when setting the maximum values stored in the temperature control and / or regulating unit.

The inventive method also has the advantage that when the sucked uncompressed gas has a very low temperature, this can be heated so far with the gas inlet heat exchanger that a freeze of the compressor can be avoided.

In an advantageous embodiment of the method according to the invention, the gas inlet heat exchanger on a gas-gas heat exchanger and the temperature control and / or regulating unit controls and / or regulates a gas inlet temperature of the uncompressed gas in the compressor by controlling and / or regulating a in a supply line of the the uncompressed gas is passed through the gas inlet heat exchanger and / or a detour channel leading past the gas inlet heat exchanger through the Ansauggasströmungsteiler. By the control and / or regulation of the intake flow divider, the amount of the uncompressed gas to be heated in the gas entry heat exchanger can be accurately determined. Accordingly, thereby the gas inlet temperature of the uncompressed gas is controlled or regulated in the compressor.

In a suitable development of the method according to the invention, the gas inlet heat exchanger has a gas-gas heat exchanger and the temperature control and / or regulating unit controls and / or regulates a gas inlet temperature of the uncompressed gas in the compressor by controlling and / or regulating a in a discharge of a gas volume flow of the compressed gas is passed through the gas inlet heat exchanger and / or through a pressure gas channel not passing through the gas inlet heat exchanger through the Abführgasströmungsteiler compressed gas of the compressor located Abführgasströmungsteiles. By adjusting the purge gas flow divider, it is determined which amount of heat of the gas compressed by the compressor is used for preheating the uncompressed gas.

In a further option of the method according to the invention, the gas inlet heat exchanger has a liquid-gas heat exchanger and the temperature control and / or regulating unit controls and / or regulates a gas inlet temperature of the uncompressed gas in the compressor by controlling and / or regulating a fluid flow divider is passed through the fluid flow divider, a fluid volume flow from a liquid cooling circuit and / or an oil circuit of the compressor through the gas inlet heat exchanger and / or in a non-passing through the gas inlet heat exchanger Fluidableitkanal. Through the fluid flow divider, the amount of fluid used to heat the uncompressed gas entering the compressor can be adjusted so that the gas inlet temperature can be set to a certain value. By means of the fluid flow divider, heating of the uncompressed gas can also be prevented by a fluid coming from, for example, a liquid cooling circuit or an oil circuit of the compressor.

Preferably, in the inventive method, the operating temperature of the compressor is monitored by at least one temperature sensor and upon setting a predetermined setpoint of the operating temperature of the compressor, the heating of the gas entering the compressor by reducing the gas and / or fluid volume flow passed through the gas inlet heat exchanger until the setting of the Setpoint lowered. This prevents the operating temperature of the compressor from exceeding the set point. As a result, the operating temperature in the present invention can always be maintained below the maximum temperature values suitable for the compressor.

It is also advantageous if in a variant of the inventive method, the temperature control and / or regulating unit is coupled to a speed control module of a drive motor of the compressor and adjusts a gas outlet temperature of the compressed gas from the compressor by adjusting the speed of the drive motor of the compressor , By adjusting the speed of the drive motor of the compressor, the volume flow and also the temperature of the compressed gas emerging from the compressor is determined. Thus can by a high Compressor speed a high gas outlet temperature and quantity and in turn a rapid heating of the entering into the compressor uncompressed gas can be achieved.

In a further embodiment of the method according to the invention, the temperature control and / or regulating unit is coupled to a pressure control module of the compressor and controls and / or regulates a gas outlet temperature of the compressed gas of the compressor by adjusting a desired gas pressure and / or by control and / or regulation a ratio of operating times and operating pauses of the compressor. By the pressure control module of the recorded power from the compressor and thus the compressor pressure is determined or controlled. For example, since the gas discharge temperature of the compressed gas depends on the pressure of the compressed gas, increasing the target gas pressure causes the gas discharge temperature to increase. For example, in a warm-up regime of the compressor, the setting of a high target gas pressure is recommended. By adjusting the ratio of operating times to operating pauses of the compressor on the one hand, the gas pressure generated by the compressor and on the other hand, the gas outlet temperature from the compressor can be effectively influenced.

In a particularly preferred embodiment of the method according to the invention, when a desired gas inlet temperature is above a current gas inlet temperature of the uncompressed gas in the compressor, the temperature control and / or regulating unit controls and / or regulates the heat output introduced into the uncompressed gas until the gas inlet temperature of the uncompressed gas corresponds to the target gas inlet temperature and a gas outlet temperature of the compressed gas corresponds to a desired gas outlet temperature. This ensures that the operating temperature of the compressor is indeed in a high temperature level, but not above the maximum permissible for the compressor temperature values.

Preferred embodiments of the present invention, their structure, function and advantages are explained in more detail below with reference to figures, wherein

1 schematically shows an embodiment of a compressor according to the invention with a gas inlet heat exchanger in the form of a gas-gas heat exchanger;

2 schematically shows a further embodiment of a compressor according to the invention with a gas inlet heat exchanger in the form of a liquid-gas heat exchanger; and

3 schematically shows a further optional embodiment of a compressor according to the invention with a throttle valve in a discharge of the compressed gas.

1 schematically shows a possible embodiment of a compressor according to the invention 1 , The compressor 1 has a compression unit 24 on. The compression unit 24 is with a supply line 2 for one in the compressor 1 entering uncompressed gas and exhaust 3 for one out of the compressor 1 coupled exiting compressed gas. That in the compressor 1 For example, incoming uncompressed gas is ambient air at ambient temperature. The ambient temperature can vary greatly depending on the respective climatic conditions. That from the compressor 1 On the other hand, escaping compressed gas has a significantly higher temperature than the uncompressed gas. This is due to the fact that the compressor 1 convert much of the energy supplied to it into heat. Typically, in compressors, only about 10% of the energy used is used to change the pressure of the gas, while about 90% is converted to heat. The compressor 1 is therefore also to be regarded as a heating device which also produces compressed air.

In the compressor according to the invention 1 is in the gas flow direction before the compression unit 24 in the supply line 2 of the uncompressed gas, a gas inlet heat exchanger 20 intended. In the illustrated embodiment, the gas inlet heat exchanger 20 a gas-gas heat exchanger. The gas inlet heat exchanger 20 is over a gas pipe 25 with the exhaustion 3 connected to the compressed gas. Between the exhaustion 3 and the gas line 25 is a purge gas flow divider 13 intended. Using the purge gas flow divider 13 Either the entire, through the compressor 1 compressed gas or part of it through the compressor 1 compressed gas or no compressed gas to the gas inlet heat exchanger 20 be directed.

Through the gas inlet heat exchanger 20 Waste heat from the compressor 1 injected into the uncompressed gas. This leads to the feeder 2 through the gas inlet heat exchanger 20 , In the feeder 2 is located in the gas flow direction in front of the gas inlet heat exchanger 20 in the 1 illustrated embodiment, a Ansauggasströmungsteiler 11 , Through the intake gas flow divider 11 Either the entire through the supply line 2 the compressor 1 fed uncompressed gas or part of this uncompressed Gas or no uncompressed gas through the gas inlet heat exchanger 20 be guided.

Depending on the volume flow and the temperature of uncompressed gas and the compressed gas, respectively through the gas inlet heat exchanger 20 be guided, the gas inlet temperature of the uncompressed gas in the compressor 1 set.

For this purpose, the Ansauggasströmungsteiler 11 and the purge gas flow divider 13 with a temperature control and / or regulating unit 5 coupled. By the temperature control and / or regulating unit 5 can the intake gas flow divider 11 and the purge gas flow divider 13 each set so that the gas inlet temperature of the uncompressed gas into the compressor 1 can be set to a predetermined setpoint.

In order to be able to adjust this setpoint appropriately, in the embodiment of FIG 1 in the supply line 2 to the compression unit 24 a temperature sensor 8th intended. Using the temperature sensor 8th can the temperature of the uncompressed gas before the compression unit 24 , ie the gas inlet temperature of the uncompressed gas in the compressor 1 to be determined. In another, not shown embodiment of the present invention may also at least one or another temperature sensor 8th for example, after the compression unit 24 during the discharge 3 be provided to the temperature of the compressor 1 to determine exiting compressed gas.

The compression unit 24 of the compressor 1 comes with a drive motor 16 driven. The speed of the drive motor 16 is in the embodiment of 1 by means of a speed control module 17 adjustable. By the speed of the engine 16 Can the pressure and thus the temperature of the compression unit 24 compressed and out of the compressor 1 exiting compressed gas.

Furthermore, in the embodiment of 1 the drive motor 16 with a pressure control module 22 coupled, by which the pressure and thus the temperature of the compressor 1 exiting compressed gas can be adjusted. Using the in the embodiment of 1 illustrated ammeter 10 can indirectly the pressure of the compressor 1 be generated compressed gas to be monitored. In addition, or instead of the amperemeter 10 The pressure of the compressed gas can be reduced by one in the exhaust 3 located pressure sensor 9 be monitored.

Further, at the compression unit 24 of the compressor 1 from 1 an operating temperature sensor 18 of the compressor 1 intended. Through the operating temperature sensor 18 can change the operating temperature of the compressor 1 be monitored to the extent that they are for the compressor 1 does not exceed the intended maximum values.

In the embodiment of 1 are at the compression unit 24 of the compressor 1 a liquid cooling circuit 6 and an oil circuit 7 intended. Using the liquid cooling circuit 6 can the waste heat in the compressor producing compressor 1 be cooled. Through the oil circuit 7 also gets waste heat from the compressor 1 removed.

2 schematically shows another possible embodiment of a compressor according to the invention 1' , The compressor 1' is essentially similar to the compressor 1 out 1 built up. Therefore, the same elements are provided with the same reference numerals. The description of these elements, which has already been made above, is hereby incorporated by reference.

In the compressor 1' from 2 is the liquid cooling circuit 6 and the oil circuit 7 via fluid lines 15 . 26 with a gas inlet heat exchanger 4 connected in the form of a liquid-gas heat exchanger. In the fluid lines 15 . 26 Fluid is passed in the form of coolant and / or oil. Although significantly more fluid lines 15 . 26 can be provided in 2 one example in the gas inlet heat exchanger 4 leading fluid line 26 and one of the gas inlet heat exchanger 4 leading fluid line 15 shown. In the fluid line 26 is a fluid flow divider 14 intended. Through the fluid flow divider 14 can do the whole, through the fluid line 26 guided fluid or only a portion of this fluid or no fluid to the gas inlet heat exchanger 4 be directed. If no fluid or only part of the fluid to the gas inlet heat exchanger 4 is passed, the remaining part of this fluid via a Fluidableitkanal 23 the fluid line 15 fed.

Through the gas inlet heat exchanger 4 carries the supply line described above 2 for the uncompressed gas. Again, it is possible that the uncompressed gas through the in the supply line 2 located Ansauggasströmungsteiler 11 completely, partially or not at all through the gas inlet heat exchanger 4 is directed.

Depending on which volume flow of uncompressed gas and fluid through the gas inlet heat exchanger 4 is passed and what temperature the respective volume flow has determined the gas inlet temperature of the uncompressed gas into the compressor 1' ,

This is in the embodiment of 2 the fluid flow divider 14 and the intake gas flow divider 11 with a temperature control and / or regulating unit 5 coupled. The temperature control and / or regulating unit 5 controls and / or regulates the intake gas flow divider 11 and the fluid flow divider 14 such that a certain, preset gas inlet temperature for the in the compressor 1' entering uncompressed gas is set. The setpoint for this gas inlet temperature is set as high as possible in the present invention, so that from the compressor 1' emerging compressed gas has the highest possible temperature, which is suitable for example directly for heating purposes.

3 schematically shows a further optional embodiment of a compressor according to the invention 1'' , Here are the same device characteristics as those in the 1 and 2 are shown, designated by like reference numerals. Reference is made to the above explanation of these device features.

The compressor 1'' points in the exhaustion 3 of the compressed gas means for adjusting the flow cross-section of the discharge 3 on, which in the illustrated embodiment by a throttle valve 24 is realized. With the throttle valve 24 the flow cross-section in the region of the compressed gas can be narrowed, whereby the flow from the compressor 1'' to be performed compression work is increased. This can increase the heating time of the compressor 1'' reduces and thus the waste heat of the compressor 1'' faster to warm up in the compressor 1'' be introduced introduced uncompressed gas.

In the embodiment of 3 monitors the throttle valve 24 upstream pressure sensor 9 the line pressure to counteract conceivable damage caused by excessive pressure peaks. These are the pressure sensor 9 and the throttle valve 24 with the temperature control and / or regulating unit 5 coupled, through which the through the throttle valve 24 released flow cross section of the exhaust 3 is adjustable or adjustable.

QUOTES INCLUDE IN THE DESCRIPTION

This list of the documents listed by the applicant has been generated automatically and is included solely for the better information of the reader. The list is not part of the German patent or utility model application. The DPMA assumes no liability for any errors or omissions.

Cited patent literature

• DE 4000997 C2 [0003]
• DE 3000044 A1 [0003]

Claims (17)

Compressor ( 1 . 1' ), with which at least one with a suction device of the compressor ( 1 ) and into the compressor ( 1 . 1' ) entering uncompressed gas into one of the compressor ( 1 . 1' ) Compressed compressed gas is generated under formation of waste heat, wherein at the compressor ( 1 . 1' ) at least one discharge device for the at least partial discharge of the waste heat of the compressor ( 1 . 1' ), characterized in that in or at the intake device at least one gas inlet heat exchanger ( 4 . 20 ) provided with the discharge device for heating the sucked uncompressed gas through at least part of the waste heat of the compressor ( 1 . 1' ), wherein the gas inlet heat exchanger ( 4 . 20 ) with a temperature control and / or regulation unit ( 5 ) is coupled to control and / or regulate a heat output introduced into the uncompressed gas. Compressor according to claim 1, characterized in that the gas inlet heat exchanger ( 20 ) has a gas-gas heat exchanger, wherein in the gas-gas heat exchanger ( 20 ) a heat exchange between the sucked uncompressed gas and the exiting compressed gas is provided. Compressor according to claim 1 or 2, characterized in that the gas inlet heat exchanger ( 4 ) has a liquid-gas heat exchanger, wherein in the liquid-gas heat exchanger ( 4 ) a heat exchange between the sucked uncompressed gas and a in a liquid cooling circuit ( 6 ) or oil circuit ( 7 ) of the compressor ( 1 . 1' ) is provided fluid. Compressor according to at least one of the preceding claims, characterized in that on the compressor ( 1 . 1' ) at least one temperature sensor ( 8th ) for a measurement of a gas inlet temperature of the uncompressed gas and / or a gas outlet temperature of the compressed gas and / or a pressure sensor ( 9 ) for an immediate and / or an ammeter ( 10 ) is provided for an indirect determination of a pressure of the compressed gas, and the temperature sensor and / or the pressure sensor ( 9 ) and / or the ammeter ( 10 ) with the temperature control and / or regulating unit ( 5 ) is coupled. Compressor according to at least one of the preceding claims, characterized in that the compressor ( 1 . 1' ) by the temperature control and / or regulation unit ( 5 ) controllable and / or controllable and in a supply line ( 2 ) of the uncompressed gas intake gas flow divider ( 11 ), wherein the uncompressed gas by means of the Ansauggasströmungsteilers ( 11 ) through the gas inlet heat exchanger ( 20 ) and / or by a at the gas inlet heat exchanger ( 20 ) bypassing channel ( 12 ) is conductive. Compressor according to claims 1 and 2, characterized in that the compressor ( 1 . 1' ) by the temperature control and / or regulation unit ( 5 ) controllable and / or controllable purge gas flow dividers ( 13 ) in a discharge ( 3 ) of the compressed gas, wherein by means of the purge gas flow divider ( 13 ) a gas volume flow of the compressed gas through the gas inlet heat exchanger ( 20 ) and / or one not through the gas inlet heat exchanger ( 20 ) leading to a pressurized gas channel for controlling and / or regulating a gas inlet temperature of the uncompressed gas into the compressor ( 1 . 1' ) and / or a working temperature of the compressor ( 1 . 1' ) is conductive. Compressor according to claims 1 and 3, characterized in that the compressor ( 1 . 1' ) by the temperature control and / or regulation unit ( 5 ) controllable and / or controllable fluid flow dividers ( 14 ), wherein through the fluid flow divider ( 14 ) a fluid volume flow through the gas inlet heat exchanger ( 4 ) and / or through one not through the gas inlet heat exchanger ( 4 ) extending Fluidableitkanal ( 23 ) for controlling and / or regulating a gas inlet temperature of the uncompressed gas into the compressor ( 1 . 1' ) and / or a working temperature of the compressor ( 1 . 1' ) is conductive. Compressor according to at least one of the preceding claims, characterized in that the compressor ( 1 . 1' ) by the temperature control and / or regulation unit ( 5 ) controllable and / or controllable and for speed control of a drive motor ( 16 ) of the compressor ( 1 . 1' ) speed control module ( 17 ) having. Compressor according to at least one of the preceding claims, characterized in that in a discharge ( 3 ) of the compressed gas means for adjusting the flow cross-section of the discharge ( 3 ) is provided. Method for operating a compressor ( 1 . 1' ), in which at least one uncompressed gas with a suction device of the compressor ( 1 . 1' ) in the compressor ( 1 . 1' sucked in and out of the compressor ( 1 . 1' ) Compressed compressed gas is compressed to form waste heat, wherein the Waste heat of the compressor ( 1 . 1' ) at least partially via at least one discharge device of the compressor ( 1 . 1' ), characterized in that the sucked uncompressed gas by a part of the waste heat of the compressor ( 1 . 1' ) in at least one gas inlet heat exchanger provided in or on the intake device ( 4 . 20 ) is heated by heat via the discharge device and the gas inlet heat exchanger ( 4 . 20 ) is passed into the sucked uncompressed gas, wherein a temperature control and / or regulating unit ( 5 ) controls and / or regulates a heat output introduced into the uncompressed gas. A method according to claim 10, characterized in that the gas inlet heat exchanger ( 20 ) has a gas-gas heat exchanger and the temperature control and / or regulating unit ( 5 ) a gas inlet temperature of the uncompressed gas into the compressor ( 1 . 1' ) by controlling and / or regulating one in a supply line ( 2 ) of the uncompressed gas of the compressor ( 1 . 1' ) intake flow divider ( 11 ) and / or regulates, whereby through the Ansauggasströmungsteiler ( 11 ) the uncompressed gas through the gas inlet heat exchanger ( 20 ) and / or one at the gas inlet heat exchanger ( 20 ) bypassing channel ( 12 ). A method according to claim 10 or 11, characterized in that the gas inlet heat exchanger ( 20 ) has a gas-gas heat exchanger and the temperature control and / or regulating unit ( 5 ) a gas inlet temperature of the uncompressed gas into the compressor ( 1 ) by controlling and / or regulating one in a discharge ( 3 ) of the compressed gas of the compressor ( 1 . 1' ) Abführgasströmungsteilers ( 13 ) and / or regulates, whereby through the Abführgasströmungsteiler ( 13 ) a gas volume flow of the compressed gas through the gas inlet heat exchanger ( 20 ) and / or through one not through the gas inlet heat exchanger ( 20 ) leading compressed gas channel. A method according to claim 10, characterized in that the gas inlet heat exchanger ( 4 ) has a liquid-gas heat exchanger and the temperature control and / or regulating unit ( 5 ) a gas inlet temperature of the uncompressed gas into the compressor ( 1 . 1' ) by a control and / or regulation of a fluid flow divider ( 14 ) and / or regulates, whereby through the fluid flow divider ( 14 ) a fluid volume flow from a liquid cooling circuit ( 6 ) or oil circuit ( 7 ) of the compressor ( 1 . 1' ) through the gas inlet heat exchanger ( 4 ) and / or into one not through the gas inlet heat exchanger ( 4 ) extending Fluidableitkanal ( 23 ). Method according to at least one of claims 12 or 13, characterized in that the operating temperature of the compressor ( 1 . 1' ) by at least one temperature sensor ( 8th ) is monitored and when setting a predetermined setpoint the operating temperature of the compressor ( 1 . 1' ) the heating of the compressor ( 1 . 1' ) entering gas by reducing by the gas inlet heat exchanger ( 4 . 20 ) guided gas and / or fluid volume flow is lowered until the setting of the setpoint. Method according to at least one of claims 10 to 14, characterized in that the temperature control and / or regulation unit ( 5 ) with a speed control module ( 17 ) of a drive motor ( 16 ) of the compressor ( 1 . 1' ) and a gas outlet temperature of the compressed gas from the compressor ( 1 . 1' ) by adjusting the speed of the drive motor ( 16 ) of the compressor ( 1 . 1' ). Method according to at least one of claims 10 to 15, characterized in that the temperature control and / or regulation unit ( 5 ) with a pressure control module ( 22 ) of the compressor ( 1 . 1' ) and a gas outlet temperature of the compressed gas of the compressor ( 1 . 1' ) by setting a target gas pressure and / or by controlling and / or regulating a ratio of operating times and operating pauses of the compressor ( 1 . 1' ) controls and / or regulates. Method according to at least one of claims 10 to 16, characterized in that when a desired gas inlet temperature above a current gas inlet temperature of the uncompressed gas into the compressor ( 1 . 1' ), the temperature control and / or regulation unit ( 5 ) controls and / or regulates the thermal power introduced into the uncompressed gas until the gas inlet temperature of the uncompressed gas corresponds to the desired gas inlet temperature and a gas outlet temperature of the compressed gas corresponds to a desired gas outlet temperature.

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