JP5553770B2 - Compressor with energy saving device and method for energy saving operation of compressor - Google Patents

Description

  The present invention relates to a compressor for a commercial vehicle for producing compressed air, the compressor having a casing having a piston chamber and a cavity, and a valve having a shield for separating the cavity from the piston chamber. And a compressor for a commercial vehicle for producing compressed air.

  Furthermore, the present invention is a method for reducing the load on a compressor for a commercial vehicle for producing compressed air, the compressor comprising a casing having a piston chamber and a cavity, and separating the cavity from the piston chamber. The present invention relates to a method for reducing the load on a compressor for a commercial vehicle for producing compressed air, which has a valve device having a shield of the above type.

  Modern commercial vehicles, for example used in rail or road traffic, have a large number of compressed air consumers. The air consumption of the compressed air consumer is generally covered by a compressed air supply device having a compressor. The compressor is driven directly by an internal combustion engine that is generally used in commercial vehicles and is used for the advancement of commercial vehicles. Since the compressor drive is directly connected to the internal combustion engine, the compressor will always rotate together as long as the commercial vehicle internal combustion engine is rotating. In particular, the compressor is operating even when the compressed air consumer does not require air or is fully filled with a compressed air reservoir provided in a commercial vehicle. In the above conditions, the compressor is generally lightened to reduce energy consumption.

  The configuration of such a load reducing device can be referred to, for example, from GB 2323639A. The energy consumption of the off-load compressor drops from about 3 KW to below 1 KW at 2000 U / min. Currently, the existing void is about 7 ccm. A void of up to about 90 ccm is possible because the void valve also acts as a throttle and the large void does not allow further energy savings. Moreover, due to the existing steps, high energy consumption during the compressor feed stroke is disadvantageous.

  The object of the present invention is to reduce the energy loss due to a continuously existing cavity while reducing the throttle action of the cavity valve.

  This object is achieved by the features of the independent claims.

  Advantageous configurations of the invention are described in the dependent claims.

  The invention is based on a configuration in which the shield can be lifted from the valve seat in the direction of the piston chamber in order to open the valve device, starting from the compressor of the type described at the beginning. By always keeping the vacant space (Schadraum) constant, the throttling effect of the valve device can be reduced by lifting the shield in the direction of the piston chamber. Moreover, such a valve device simply requires a seal and a spring.

  Advantageously, the shield may be at least partially movable in the notch of the cylinder head adjacent to the piston chamber.

  The shield may be movable at least partially in the piston chamber. In this configuration, the shield lifted from the valve seat at least partially plunges into a cutout located in the piston at a return point on the upper side of the piston that is movable in the piston chamber. In this arrangement, the always provided void is reduced during the pumping stroke, and less energy is lost unnecessarily during the compression stroke, thus increasing the overall efficiency of the compressor. The minimum required bottom surface of the cut portion is at least the same as the bottom surface of the shield, and the height of the cut portion is the same as the section where the shield is only lifted from the valve seat.

  Advantageously, the void may be connected to the atmosphere. Due to the connection between the void and the atmosphere, it is possible to further reduce the peak pressure generated during the load reduction process compared to a closed void. This further reduces the energy consumption of the compressor.

  Other valve devices with other shields and other piston chambers are provided, the other shields being held in the direction from the other valve seats to the other piston chambers for opening the other valve devices. It is also possible to consider that it is possible to go up. In addition to the single cylinder compressor, a compressor having two or more cylinders is also used. Each valve device that opens in the direction of the other piston chamber may be provided to reduce the load on the compressor.

  Other shields may be adapted to be at least partially movable into other notches in the cylinder head adjacent to other piston chambers.

  Advantageously, the other shield may be at least partially movable into the other piston chamber. Other shields lifted from other valve seats at least partially plunged into other notches located in other pistons at return points above other pistons that are movable in other piston chambers. To do.

  Further, when the valve device and the other valve device are opened, the piston chamber and the other piston chamber may be connected to each other through a void. The connection between the piston chamber and the other piston chamber through the space allows the air between the piston chamber and the other piston chamber to be pumped back and forth, so that pressure formation during the load reduction process of the compressor is It is sufficiently prevented.

  Alternatively, other cavities that can be connected to other piston chambers via other valve devices may be provided. By providing another space, it is possible to reduce the load on the piston chamber and the other piston chamber separately.

  In particular, other voids may be connected to the atmosphere.

  Furthermore, this invention provides the commercial vehicle provided with the compressor based on this invention.

  The method described in the superordinate conception is further improved by lifting the shield from the valve seat in the direction of the piston chamber for opening the valve device. Thus, the advantages and characteristics of the compressor according to the invention are also replaced by the scope of the method.

  This also applies to the advantageous configuration of the method according to the invention described below.

  The method according to the present invention advantageously allows the shield to be at least partially in the notch of the cylinder head adjacent to the piston chamber, while the piston movable in the piston chamber is near the lower return point. It is improved by exercising. The movement of the shield while the movable piston in the piston chamber is near the lower return point is particularly simple because the pressure in the piston chamber at this point is small.

  Advantageously, the shield may be adapted to move at least partially in the piston chamber while the piston movable in the piston chamber is near the lower return point. The shield lifted from the valve seat is at least partially accommodated by a notch arranged in the piston at a return point above the piston.

  Further, the void may be connected to the atmosphere.

  It is also possible to consider that other valve devices with other shields and other piston chambers are provided. The other shield is lifted from the other valve seat in the direction of the other piston chamber to open the other valve device.

  Advantageously, the other shield moves at least partially in another notch in the cylinder head adjacent to the other piston chamber.

  In particular, the other shield may be adapted to move at least partially into the other piston chamber while the other piston movable in the other piston chamber is near the lower return point. Other shields lifted from other valve seats are at least partially accommodated by other notches located in the other pistons at return points above the other pistons.

  The piston chamber and the other piston chamber may be connected to each other through a space.

  Advantageously, a cavity may be provided which is connected to another piston chamber via another valve device.

  In particular, other voids may be connected to the atmosphere.

It is sectional drawing of the 1st compressor which concerns on this invention. It is detail drawing of the 1st cylinder head which concerns on this invention. It is detail drawing of the 1st cylinder head which concerns on this invention in a pressure stroke. It is detail drawing of the 1st cylinder head which concerns on this invention in a load reduction process. It is the figure which showed a part of 2nd compressor which concerns on this invention. It is the figure which showed a part of 3rd compressor which concerns on this invention. FIG. 7a is a diagram showing the suction stroke of the compressor with reduced load, FIG. 7b is a diagram showing the compression stroke of the compressor with reduced load, and FIG. 7c shows another suction stroke of the compressor with reduced load. FIG. It is the figure which showed the compressor by which load was reduced. FIG. 9A is a first graph specifically showing energy saving due to load reduction, and FIG. 9B is a second graph specifically showing energy saving due to load reduction.

  The invention will be described by way of example on the basis of particularly advantageous embodiments with reference to the accompanying drawings.

  The same reference numerals used in the drawings indicate the same or similar members.

  FIG. 1 shows a sectional view of a first compressor according to the present invention. The illustrated compressor 10 includes a casing 14 having a piston chamber 16 and a cylinder head 28. A piston 30 that is movable in the piston chamber 16 is disposed in the piston chamber 16. The piston 30 is driven by a crankshaft 36 via a connecting rod 34. A space 18 and a valve device 20 including a valve seat 24 provided behind the shield 22 and the notch 26 are disposed in the cylinder head 28. By switching the valve device 20, the connection between the cavity 18 and the piston chamber 16 can be released, as will be described in detail below.

  FIG. 2 shows a detailed view of the first cylinder head according to the present invention. In addition to the members shown in FIG. 1, a spring 46, a support plate 48, a seal ring 50, a valve plate 52 and a connection chamber 54 are shown. The valve plate 52 is provided with a notch 26 having a valve seat 24. A shield 22 is seated on the valve seat 24 in the closed state as described for the valve device 20. The shield 22 is pressed against the valve seat 24 by a spring 46 supported by a support plate 48. The seal ring 50 seals the connection chamber 54. The shield 22 advances into the notch 26 against the spring force of the spring 46 by the ventilation of the connection chamber 54.

  3 and 4 are different views showing in detail the first cylinder head according to the present invention in the pumping stroke or the load reducing stroke. The components of the cylinder head 28 shown in FIGS. 3 and 4 are substantially the same as those already described in FIG. FIG. 3 shows the valve device 20 in the closed state, and FIG. 4 shows the same valve device 20 in the advanced state. In the advanced state, the connection chamber 54 is ventilated, and as a result, the shield 22 advances into the notch 26. That is, the shield 22 is lifted from the valve seat 24.

  FIG. 5 shows a part of the second compressor according to the present invention. The part of the compressor 10 shown in FIG. 5 differs from the first embodiment in that the notch 26 is not provided in the valve plate 52. The shield 22 is flush with the valve plate 52 in the entered state. However, in order to allow the shield 22 to advance, a notch 32 is provided in the piston 30. The shield 22 can advance into the cut portion 32. In the advanced state, the shield 22 partially enters the notch 32 at the return point on the upper side of the piston 30. When the shield 22 is advanced, a connection through which air can flow is provided between the cut portion 32 and the space 18 by ventilation of the connection chamber 54.

  FIG. 6 shows a part of a third compressor according to the present invention. The compressor 10 illustrated in FIG. 6 is a compressor having two cylinders. In addition to the members already described, the compressor 10 shown in FIG. 6 includes another piston chamber 16 ', another cavity 18', another shield 22 ', another valve seat 24' and other springs. It has another valve device 20 'with 46' and another piston 30 'with another notch 32'. In this embodiment of the compressor 10, the space 18 is not connected to the other space 18 ′, and the two spaces 18, 18 ′ are separately provided for reducing the load on the two cylinders. The valve devices 20 and 20 'can be connected. It is also possible to consider that the two cavities 18, 18 ′ are connected to each other, so that when the valve device 20 and the other valve device 20 ′ are opened simultaneously, the piston chamber 16 and the other piston chamber 16. A connection is provided through which air can flow. The above embodiment is described in detail in FIG. As shown in FIGS. 1 to 4, the arrangement of the valve device 20 and the other valve device 20 ′ in the two notches as described above with respect to the twin cylinder compressor having the cut portion 32 and the other cut portion 32 ′. Can also be considered.

  7a, 7b and 7c show the working process of the compressor 10 with reduced load. FIG. 7a shows the compressor 10 with the valve device 20 opened to reduce the load on the compressor 10 during the last work timing. During the first suction stroke in which the piston 30 moves away from the valve device 20, air is sucked from the air suction portion 42 into the piston chamber 16 through the air suction valve 38. During the first suction stroke, the air exhaust valve 40 remains closed and no air is pumped into the air exhaust 44.

  Following the first suction stroke, the piston 30 again moves towards the valve device 20. The air suction valve 38 is closed based on the absence of negative pressure, and the air discharge valve 40 is not ideally opened based on the low pressure in the piston chamber 16. Since the valve device 20 is open, that is, the piston chamber 16 and the cavity 18 are connected, the compressor 10 sucks air into the cavity 18 during this stroke. Accordingly, air is drawn into the cavity 18 and compressed. The achievable pressure ideally remains below the pressure present at the air exhaust 44.

  In the other suction stroke shown in FIG. 7c, the piston moves again away from the valve device 20 as in FIG. 7a, but the air suction valve 38 and the air exhaust valve 40 remain closed. During the other suction stroke, the compressed air drawn into the void is returned to the piston chamber 16 and expanded.

  FIG. 8 shows a compressor with reduced load. The compressor 10 shown in FIG. 8 is a compressor provided with two cylinders. The piston chamber 16 and the other piston chamber 16 'can be connected via the space 18 by opening the valve device 20 and the other valve device 20'. A piston 30 or 30 'connected to the crankshaft 36 via a connecting rod 34 or 34' is arranged inside the piston chamber 16 and the other piston chamber 16 '. When both the valve device 20 and the other valve device 20 'are open, the load on the compressor 10 is reduced. During the periodic up and down movement of the piston 30 and the other piston 30 ′, air is pumped back and forth between the two piston chambers 16, 16 ′ via the cavity 18. Ideally, neither a negative pressure nor a positive pressure is formed inside, so that the air intake valves 38, 38 'and the air exhaust valves 40, 40' remain closed. That is, the compressor does not suck air through the two air suction portions 42 and 42 'in a state where the load is reduced.

FIGS. 9a and 9b show two graphs specifically showing energy savings by reducing the load on the compressor. The X-axis of the two graphs shows the compressor rotation speed per minute, and the Y-axis shows each energy consumption in kilowatt hours. FIG. 9a shows four curves for a 250 cm ³ compressor. Curves 104 and 106 show the energy consumption at a pumping pressure of 8.5 or 12 bar. Curves 100 and 102 show two different energy saving modes of the compressor. These energy saving modes can be realized by reducing the load. The four curves described in FIG. 9b are for a 360 cm ³ compressor, the upper two curves 112, 114 also correspond to a pumping pressure of 8.5 or 12 bar, the lower two curves 108 and 110 also show two different energy saving modes of the compressor that can be realized by reducing the load.

  The features of the invention disclosed in the above description, drawings and claims may be important for the realization of the invention both individually and in any combination.

  10 compressor, 12 commercial vehicle, 14 casing, 16 piston chamber, 16 'other piston chamber, 18 void, 18' other void, 20 valve device, 20 'other valve device, 22 shield, 22' other 24 valve seat, 24 'other valve seat, 26 notch, 28 cylinder head, 30 piston, 30' other piston, 32 notch, 32 'other notch, 34 connecting rod, 34' other Connecting rod, 36 Crankshaft, 38 Air intake valve, 38 'Air intake valve, 40 Air exhaust valve, 40' Air exhaust valve, 42 Air intake part, 42 'Air intake part, 44 Air exhaust part, 46 Spring, 46' etc. Spring, 48 support plate, 50 seal ring, 52 valve plate, 54 connection chamber, Energy saving mode of compressor at 00 225 ccm, energy saving mode of compressor at 102 225 ccm, 104 compressor of 225 ccm at pressure of 8.5 bar, 106 compressor of 225 ccm at pressure of 12 bar, energy saving mode of compressor of 108 360 ccm, 110 360 ccm Energy-saving mode in compressor, 112 compressor of 360 ccm at a pressure of 8.5 bar, 114 compressor of 360 ccm in a pressure of 12 bar

Claims (15)

A compressor (10) for a commercial vehicle (12) for producing compressed air, the compressor (10) comprising:
-Having a casing (14) with a piston chamber (16) and a cavity (18), and
- have a valve device provided with shields for separating the cavity (18) from the piston chamber (16) and (22) (20),
For opening of the shield (22) is a valve device (20), Ri separably der in the direction of the piston chamber from the valve seat (24) (16),
The shield (22) is at least partially movable into the piston chamber (16), and the shield (22) spaced from the valve seat (24) is a piston (30) movable in the piston chamber (16). ) Above the valve plate (52) in a state where the shield (22) is not spaced apart and at least partially plunges into the notch (32) located in the piston (30). A compressor for commercial vehicles for producing compressed air, characterized in that it is flush . Cavity (18) is characterized in that it is connected to the atmosphere, claim 1 Symbol mounting of the compressor. -Another valve device (20 ') with another shield (22') and another piston chamber (16 ') are provided,
The other shield (22 ') can be separated from the other valve seat (24') in the direction of the other piston chamber (16 ') for the opening of the other valve device (20'). wherein, according to claim 1 or 2 compressor according. The other shield (22 ') is at least partially movable into the other piston chamber (16'), and the other shield (22 ') spaced from the other valve seat (24') At least at the return point above the other piston (30 ') movable in the other piston chamber (16') into the other notch (32 ') located in the other piston (30') The compressor according to claim 3 , wherein the compressor partially enters. The piston chamber (16) and the other piston chamber (16 ′) are connected to each other via a space (18) when the valve device (20) and the other valve device (20 ′) are opened. The compressor according to claim 3 or 4 , wherein the compressor is provided. Other valve device (20 ') via the other of the piston chamber (16') other cavity is connectable to (18 '), characterized in that is provided, according to claim 3 or 4, wherein compressor. Compressor according to claim 6 , characterized in that the other cavity (18 ') is connected to the atmosphere. Compressor of any one of claims 1 to 7 (10) to comprise the commercial vehicle (12). A method for reducing the load on a compressor (10) for a commercial vehicle (12) for producing compressed air, the compressor (10) comprising:
-Having a casing (14) with a piston chamber (16) and a cavity (18), and
- have a valve device provided with shields for separating the cavity (18) from the piston chamber (16) and (22) (20),
Reduce the load on the compressor for commercial vehicles for producing compressed air , separating the shield (22) from the valve seat (24) in the direction of the piston chamber (16) to open the valve device (20). In the way to
While the piston (30) movable in the piston chamber (16) is located near the lower return point, the shield (22) is moved at least partially into the piston chamber (16) and the valve seat ( The shield (22) spaced from 24) is at least partially accommodated at the return point on the upper side of the piston (30) by a notch (32) arranged in the piston (30), and the shield (22) A method for reducing the load on a compressor for a commercial vehicle for producing compressed air, characterized in that it is flush with the valve plate (52) when not spaced apart . 10. Method according to claim 9 , characterized in that the void (18) is connected to the atmosphere. Another valve device (20 ′) having another shield (22 ′) and another piston chamber (16 ′) are provided, and the other shield (22 ′) is connected to another valve device ( 11. Method according to claim 9 or 10 , characterized in that, for the opening of 20 '), it is spaced from the other valve seat (24') in the direction of the other piston chamber (16 '). While the other piston (30 ') movable in the other piston chamber (16') is located near the lower return point, the other shield (22 ') is moved to the other piston chamber (16'). The other shield (22 '), which is at least partially moved inwardly and spaced from the other valve seat (24'), is placed at the other piston (30 ') at the return point above the other piston (30'). 12. Method according to claim 11 , characterized in that it is at least partly accommodated by another incision (32 ') arranged in'). 13. Method according to claim 11 or 12 , characterized in that the piston chamber (16) and the other piston chamber (16 ') are connected to each other via a cavity (18). 13. A method according to claim 11 or 12 , characterized in that another cavity (18 ') is provided which connects to another piston chamber (16') via another valve device (20 '). 15. A method according to claim 14 , characterized in that another cavity (18 ') is connected to the atmosphere.

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