KR101517240B1 - Hydraulic circuit for construction machinery - Google Patents

Abstract

The hydraulic circuit of the construction machine according to the present invention includes a first traveling motor 101 and a first front work machine 112 (121) via a first traveling control valve 100 and a first front control valve 110 The second driving motor 141 and the second front work machine 151 are connected to each other through the second travel control valve 140 and the second front control valve 150, A third pump P3 for supplying operating fluid to the swing motor 171 through the swing control valve 170 and a second pump P2 for supplying hydraulic fluid to the first pump P3 A first joining line 196 for joining working fluid to the working fluid of the first pump P1 at the front end of the first front control valve 110 and 120, A second merging line 197 for merging the working fluid of the third pump P3 and the working oil of the second pump P2 at the front end of the front control valve 150, (191), (192), and (193), and the signal pressure Pa4 (Pb4) is applied to the construction machine including the drain line 195 which drains through the control valve 170 (Pa5) (Pb5) applied to the pressure receiving portion 190a and the signal pressure Pa4 (Pb4) (Pa5) (Pb5) applied to the pressure receiving portion 190a, A travel straight-ahead valve 190 that converts in a range of the third positions 191, 192, and 193; And a swing parallel line (172) for bypassing the running straight valve (190) and supplying the hydraulic fluid of the third pump (P3) to the swing control valve (170) The third pump P3 and the drain line 195 communicate with the first pump and the third pump P3 and the first and second merging lines 196 ) 197 is disconnected and the travel straightening valve 190 is converted to the second position 192 and the third pump P3 is connected to the first junction 192 via the first flow path 192a, The third pump P3 is communicated with the second merging line 197 via the second flow path 192b and the third pump P3 is connected to the third pump P3 via the third flow path 192c, The third pump P3 communicates with the drain line 195 at a second opening amount smaller than the first opening amount and the third forward opening valve 190 is converted into the third position 193, My 1 and the second merging lines 196 and 197, respectively, and the connection between the third pump P3 and the drain line 195 is cut off.

Front work, running, turning, compound operation, turning impact, running straight valve, linear control

Description

HYDRAULIC CIRCUIT FOR CONSTRUCTION MACHINERY

BACKGROUND OF THE INVENTION 1. Field of the Invention The present invention relates to a construction machine such as an excavator, and more particularly, to a hydraulic circuit of a construction machine capable of preventing a turning impact caused by a sudden turn when a front operation and a combined traveling and turning operation are simultaneously performed.

Generally, in a construction machine such as an excavator, a vehicle is driven by a traveling motor serving as a hydraulic motor, the upper revolving body is revolved by a revolving motor which is a hydraulic motor, and a front working machine such as a boom, an arm and a bucket cylinder is driven do.

In this way, all of the drive units are driven by the hydraulic oil, and the hydraulic oil discharged from the pump must be appropriately distributed to the respective drive units. Particularly, when the running, the front working machine, or the turning operation are simultaneously performed, the flow rate of the hydraulic fluid supplied to either the left traveling motor or the space row motor becomes insufficient, the construction machine can not go straight. In order to solve this problem, a traveling straight-ahead valve is installed so that a sufficient flow rate can be supplied to the traveling motor. One example of such a hydraulic circuit is shown in Figs. 1A to 1C.

1A, the running straight ahead valve 30 connects the first gear pump 10 to the drain line 40 in an initial state to drain the hydraulic oil discharged from the first gear pump 10, The pump 10 is disconnected from the first and second merging lines 41 and 42. On the other hand, the operating oil of the first gear pump 10 is waiting at the front end of the swing control valve 50 through the swing parallel line 43 connected to the swing control valve 50, bypassing the traveling straight ahead valve 30.

In this state, when the travel signal and the arm operation signal are generated, the first travel control valve 60 and the arm first-speed control valve 70 are converted into the state shown in FIG. 1B. The first drive control valve 60 and the arm first speed control valve 70 thus cut off the first and second branch signal lines 32 and 33 connected to the second gear pump 20. Then, a high pressure is formed in the traveling straight line 31 connecting the hydraulic pressure receiving portion 30a of the traveling straight ahead valve 30 and the second gear pump 20. Whereby the traveling straight-ahead valve 30 is converted into the state shown in Fig. 1B.

1B, the first gear pump 10 is connected to the first and second merging lines 41 and 42 via the straight traveling valve 30. The first and second gear pumps 10 and 30 are connected to the first and second merging lines 41 and 42, respectively. As a result, the hydraulic fluid discharged from the first gear pump 10 is supplied to the boom first-speed control valve 90 through the first coupling line 41 and is supplied through the second coupling line 42 to the arm 1 And supplies the operating oil to the control valve (70). On the other hand, the first running control valve 60 is supplied with the hydraulic oil by the main pump P1.

The first and second merging lines 41 and 42 are communicated with the swivel parallel line 43 through the traveling straight-ahead valve 30. The operating fluid flowing through the first and second merging lines 41 and 42 is supplied to the boom first speed control valve 90 and the arm first speed control valve 70 at the front end thereof, . On the other hand, however, the operating pressure of the boom and arm is about 100 bar. Accordingly, a pressure of about 100 bar is formed in the first and second merging lines 41 and 42 and the swirling parallel line 43 is also communicated with the first and second merging lines 41 and 42 Since the drain line 40 is blocked by the traveling straight-ahead valve 30, the drain line 40 is formed to be about 100 bar. On the other hand, the turning operation pressure is about 50 bar. Accordingly, when the swing control valve 50 is changed from left to right in the state as shown in FIG. 1B, the high-pressure, high-flow hydraulic oil of about 100 bar is supplied to the swing motor 51 through the swing control valve 50 do. As a result, the swing motor 51 is suddenly driven, causing the upper swing body to turn at a sudden rapid speed. Such a phenomenon may be referred to as a turning shock. In the case of such a turning impact, there is a high possibility of a safety accident because the upper revolving body turns suddenly unlike the driver's intention.

On the other hand, when the traveling, the front work and the swing drive are simultaneously performed, most of the operating oil discharged from the first gear pump 10 is supplied to the swing motor 51 because the operating pressure of the boom and the arm is relatively large. In other words, only the operating oil supplied to the boom cylinder and the arm cylinder through the first and second merging lines 41 and 42 is minimal. For this reason, the driving speed of the front working machine is remarkably lowered and the efficiency of the work is lowered.

Particularly, since not only the boom but also the loads of the arm and the bucket are applied to the boom cylinder, high pressure is formed in the rising chamber of the boom cylinder. Therefore, in the case where only the second running control valve (not shown) is changed by about half, a part of the operating oil of the main pump P1 is supplied to the traveling motor through the running control valve (not shown) Speed control valve 90 to the boom cylinder. However, when the operating fluid of the main pump is joined to the first merging line 41 at the front end of the boom first speed control valve 90 and the operating pressure of the swing motor 51 is about 50 bar The hydraulic fluid to be supplied to the boom cylinder must flow back to the swivel parallel line 43 through the first joining line 41 and the traveling straight-ahead valve 30. Therefore, Therefore, a larger flow rate of hydraulic fluid is supplied to the swing motor 51, which not only increases the swinging impact, but also causes a problem that the driving speed of the boom cylinder is remarkably lowered.

On the other hand, the hydraulic pressure receiving portion 30a of the traveling straight-ahead valve 30 is communicated with the second gear pump 20 so that when the traveling control valve 60 and the front control valve 70 are simultaneously converted, (30) is suddenly converted into a state as shown in FIG. That is, the traveling straight ahead valve 30 is converted to the ON / OFF system. As a result, the drain line 40 is suddenly shut off because the traveling straight-ahead valve is switched to the on / off system, thereby suddenly generating a large pressure in the swirling parallel line 43. These factors further amplify the turning impact. Reference numeral 80 denotes a boom second-speed control valve having a function of controlling an optional device.

SUMMARY OF THE INVENTION The present invention has been made in view of the foregoing points, and it is an object of the present invention to provide a hydraulic circuit of a construction machine capable of preventing a turning impact and preventing a driving speed of a front working machine from being lowered during a combined operation .

In order to achieve the above object, the hydraulic circuit of the construction machine according to the present invention comprises a first traveling motor 101 and a second traveling motor 101 through a first traveling control valve 100 and a first front control valve 110, A first pump P1 for supplying working oil to each of the first front working machines 112 and 121 and a second pump P1 for supplying working oil to the second traveling motors 141 and 141 through the second traveling control valve 140 and the second front control valve 150, A third pump P3 for supplying operating oil to the swivel motor 171 through the swivel control valve 170, a second pump P2 for supplying working fluid to the second front work machine 151, A first merging line 196 for merging the operating oil discharged from the third pump P3 with the operating oil of the first pump P1 at the front end of the first front control valve 110 and 120, A second joining line 197 joining the working oil of the pump P3 to the working oil of the second pump P2 at the front end of the second front control valve 150, And a drain line 195 for draining the hydraulic fluid of the third pump P3 through the swing control valve 170. The first to third positions 191 and 192 And a signal pressure Pa4 (Pb4) (Pb4) applied to the pressure-receiving portion 190a, which has a pressure-receiving portion 190a to which the signal pressure Pa4 (Pb4) (191), (192), and (193) according to the magnitude of the first and the second position (Pa5) and (Pb5). And a swing parallel line (172) for bypassing the running straight valve (190) and supplying the hydraulic fluid of the third pump (P3) to the swing control valve (170) The third pump P3 and the drain line 195 communicate with the first pump and the third pump P3 and the first and second merging lines 196 ) 197 is disconnected and the travel straightening valve 190 is converted to the second position 192 and the third pump P3 is connected to the first junction 192 via the first flow path 192a, The third pump P3 is communicated with the second merging line 197 via the second flow path 192b and the third pump P3 is connected to the third pump P3 via the third flow path 192c, The third pump P3 communicates with the drain line 195 at a second opening amount smaller than the first opening amount and the third forward opening valve 190 is converted into the third position 193, My 1 and the second merging lines 196 and 197, respectively, and the connection between the third pump P3 and the drain line 195 is cut off.

According to an embodiment of the present invention, the hydraulic circuit of the construction machine includes the driving signal pressures Pa4, Pb4, Pa5, and Pb5 applied to the first and second travel control valves 100, A shuttle valve unit 194 for applying a large signal pressure to the pressure receiving portion 190a of the traveling straight-ahead valve 190; A straight running signal line 103 for connecting the shuttle valve unit 194 and the pressure receiving portion 190a of the traveling straight ahead valve 190; A first branch signal line 103a branching from the traveling straight line 103 and sequentially passing through the first and second travel control valves 100 and 140 to be connected to the drain line; Further comprising a second branch signal line (103b) passing through the first and second front control valves (110), (120) and (150) respectively and connected to the drain line, the first and second drive control valves 100, and 140 is shifted from the neutral state and at least one of the first and second front control valves 110, 120, and 150 is converted to be out of the neutral state, The signal lines 103a and 103b in the second branch are cut off from the drain line.

In addition, the hydraulic circuit of the construction machine may further include a hydraulic pump for preventing hydraulic fluid discharged from the first pump (P1) from flowing back to the swivel parallel line (172) through the first merging line (196) And a check valve (198) provided between the traveling straight ahead valve (P3) and the traveling straight ahead valve (190).

The above-described object is achieved by providing the first traveling motor 101 and the first front working machines 112, 121 via the first traveling control valve 100 and the first front control valves 110, A first pump P1 for supplying working fluid to the first traveling motor 141 and a second front working machine 151 via the second traveling control valve 140 and the second front control valve 150, A third pump P3 for supplying operating fluid to the swing motor 171 via the swing control valve 170 and a third pump P3 for supplying operating fluid discharged from the third pump P3 A first merging line 196 for merging the working fluid of the first pump P1 with the working fluid of the first pump P1 at the front end of the first front control valve 110 and 120, A second merging line 197 for merging the hydraulic fluid of the third pump P3 with the hydraulic fluid of the second pump P2 at the front end of the working machine 151, (Pb4) (Pa5) (Pb5) is applied to a hydraulic circuit applied to a construction machine including a drain line (195) for draining a hydraulic fluid through a hydraulic circuit (170) The straight run valve 290 is switched between the first position 291 and the second position 292 according to the magnitude of the signal pressure Pa4 (Pb4) (Pa5) (Pb5) applied to the pressure receiving portion 290a. ; A swivel parallel line 172 that bypasses the traveling straight ahead valve 290 and connects the third pump P3 and the swing control valve 170; And a driving signal pressure Pa4 (Pb4) (Pa5) (Pb5) applied to the first and second traveling control valves 100 and 140, The third pump P3 is connected to the drain line 195 and the third line P3 when the traveling straight line valve 290 is switched to the first position 291. [ And the connection between the third pump P3 and the first and second merging lines 196 and 197 is blocked and when the traveling straightening valve 290 is converted into the second position 292, The third pump P3 is connected to each of the first and second merging lines 196 and 197 and the connection between the third pump P3 and the drain line 195 is blocked. The hydraulic circuit of Fig.

According to the above-mentioned problem, the traveling straight-ahead valve is provided with a second position in which the first and second merging lines and the third pump are communicated with each other and the drain line is connected to the third pump, The third pump can reduce the flow rate and the pressure of the hydraulic fluid supplied to the swing motor through the swing parallel line and the swing control valve during the swing complex operation, thereby preventing the swinging shock in which the sudden swing motion occurs .

Further, by applying the traveling signal pressure to the pressure receiving portion of the traveling straight-ahead valve, the amount of change of the traveling straight-ahead valve can be linearly controlled in accordance with the amount of operation of the traveling control portion, It is possible to prevent the supply of the high-pressure, high-flow amount of the operating fluid suddenly, thereby completely preventing the turning impact.

On the other hand, a check valve may be provided between the third pump and the traveling straight-ahead valve to prevent the working fluid of the first pump from flowing backward to the swing balance line through the first joining line and the traveling straight- So that it is possible to improve the driving speed of the front working machine.

Hereinafter, a hydraulic circuit of a construction machine according to an embodiment of the present invention will be described in detail.

Referring to FIG. 2, in the hydraulic circuit of the construction machine according to an embodiment of the present invention, when the front work, the running and the turning of the upper revolving body are simultaneously performed, the upper revolving body is rotated will be. The hydraulic circuit of such a construction machine includes a travel straightening valve 190, a shuttle valve unit 194 and a swiveling parallel line 172.

The working machine of the construction machine to which the present embodiment is applied is driven by the operating oil discharged from the first to third pumps P1, P2, and P3.

More specifically, the first pump P1 includes a first travel control valve 100, a boom first-speed control valve 110, a bucket control valve 120, and an arm second-speed control valve 130, The hydraulic oil is supplied to the first traveling motor 101, the boom cylinder 112, the bucket cylinder 121 and the arm cylinder 151, Of course, the operating oil supplied through the arm second-speed control valve 130 is joined to the arm cylinder 151 by operating oil discharged from the second pump P2. However, when the first travel control valve 100 is completely shifted to one side or the other side out of the neutral state, the operating fluid of the first pump P1 is supplied to the respective control valves 110 ) 120 (130) is blocked and supplied only to the first traveling motor (101) through the first traveling control valve (100). In such a situation, the traveling rectilinear valve 190 is changed so that the operating fluid of the third pump P3 is supplied to the boom first speed control valve 110, the bucket control valve 120, And supplies it to the second-speed control valve 130. This operation will be described in detail below. The boom first speed control valve 110 and the bucket control valve 120 are defined as first front control valves 110 and 120 and the boom cylinder 112 and the bucket cylinder 121 are connected to the first front work machine 112) (121).

The second pump P2 includes a second travel motor 141 through a second travel control valve 140, a first-arm control valve 150 and a second boom second-speed control valve 160, The boom cylinder 151, and the boom cylinder 112, respectively. Of course, the hydraulic fluid supplied through the boom second-speed control valve 160 joins with the hydraulic fluid discharged from the first pump P1 and is supplied to the boom cylinder 112. [ However, when the second travel control valve 140 is completely shifted to the one side or the other side out of the neutral state, the operating oil of the second pump P2 is supplied to the respective control valves 150 ) 160 and is supplied only to the second traveling motor 141 through the second traveling control valve 140. In this situation, the running straight valve 190 is changed so that the operating fluid of the third pump P3 is supplied to the boom second-speed control valve 160 and the arm first-speed control valve 150 through the second joining line 197, . Here, the arm first-speed control valve 150 is defined as a second front control valve 150, and the arm cylinder 151 is defined as a second front worker 151.

The third pump P3 supplies the hydraulic fluid to the swing control valve 170 and the dozer control valve 180 through the swivel parallel line 172 and the dozer parallel line 182. [ However, as described above, when any one of the first and second travel control valves 100 and 140 is converted, the third pump P3 is operated through the first and second merging lines 196 and 197, The first and second front control valves 110, 120 and 150, respectively.

As described above, when the traveling signal is inputted, the traveling rectilinear valve 190 switches the first and second pumps P1 (P1, P2) supplied to the first and second front control valves 110, The first and second front control valves 110, 120, and 150 are operated to supply the operating fluid of the third pump P3. The traveling rectilinear valve 190 includes a pressure receiving portion 190a and is provided with first to third positions 191, 192 and 193 which are changed according to the magnitude of the signal pressure applied to the pressure receiving portion 190a Respectively.

The first position 191 connects the third pump P3 and the drain line 195 by a first opening amount and the first and second merging lines 196 and 197 and the third pump P3 ). This state is an initial state of the traveling straight ahead valve 190 and is not running. That is, the first and second travel control valves 100 and 140 are located in the neutral state. In this state, the hydraulic fluid discharged from the third pump P3 is drained through the drain control valve 170 and the dozer control valve 180 along the drain line 195. The first and second front control valves 110, 120 and 150 are supplied with operating fluid discharged from the first and second pumps P1 and P2.

The second position 192 is a transitional position before the travel straightening valve 190 is converted to the third position 193. The first position of the second position 192 is connected to the first pump 192 and the third pump P3 is connected to the first joining line 196 and the second joining line 197, And a third flow path 192c for communicating the operating fluid of the third pump P3 with the drain line 195 are formed in the second flow path 192b. The third flow path 192c drains the operating fluid of the third pump P3 to the drawn line 195 with a second opening amount smaller than the first opening amount. The hydraulic fluid flow rate of the third pump P3 drained to the drain line 195 through the third flow path 192c is smaller than the hydraulic fluid flow rate of the third pump P3 drained from the first position 191 to the drain line 195 P3). By forming the third flow path 192c and draining a part of the operating oil of the third pump P3 to the drain line 195 as described above, the rotation of the swing motor (not shown) through the swing parallel line 172 and the swing control valve 170 It is possible to reduce the flow rate and pressure of the operating oil supplied to the swing motor 171, thereby preventing the swing motor 171 from being rapidly driven. That is, it is possible to prevent the turning impact.

The third position 193 communicates the third pump P3 with each of the first and second merging lines 196 and 197 and connects the third pump P3 and the drain line 195 Disconnect the connection.

On the other hand, a check valve 198 is provided at the front end of the straight traveling valve 190. The check valve 198 is configured such that when the traveling straight valve 190 is switched to the second and third positions 192 and 193 and the hydraulic oil flows back to the swivel parallel line 172 through the first merging line 196 . The reverse flow occurs to the swivel parallel line 172 through the first merging line 196 as follows.

A part of the operating fluid of the first pump P1 is supplied to the first traveling motor 101 through the first traveling control valve 100 when the first traveling control valve 100 is not completely converted And the remaining part of the hydraulic fluid of the first pump (P1) is supplied to the boom first-speed control valve (110) through the boom first-speed parallel line (111). The working oil pressure of the boom first-parallel line 111 is twice as high as the pressure of the second parallel line 172. Accordingly, when the boom first-speed control valve 110 is changed to be out of the neutral state, the operating fluid of the boom first-speed parallel line 111 discharged from the first pump P1 flows through the first joining line 196, To the swivel parallel line (172) through the traveling rectilinear valve (190). In this case, the flow rate of the hydraulic fluid supplied to the swing motor 171 further increases, the swinging impact is further increased, and the driving speed of the boom cylinder 112 is lowered. When the check valve 198 for preventing this is installed at the front end of the straight running valve 190, this reverse flow can be prevented, the driving speed of the boom cylinder 112 can be secured, .

The shuttle valve unit 194 is for applying the travel signal pressure Pa4 (Pb4) (Pa5) (Pb5) to the pressure receiving portion 190a of the traveling rectilinear valve 190. Such a shuttle valve unit 194 applies a large signal pressure Pa5 among the signal pressures Pa4, Pb4 (Pa5) and Pb5 output from the travel control section 104 to the pressure receiving section 190a. The running signal pressure Pa4 (Pb4) (Pa5) (Pb5) is applied to the pressure receiving portion 190a of the traveling straight-ahead valve 190 through the shuttle valve unit 194, The magnitude of the signal pressure applied to the pressure receiving portion 190a of the traveling straight-ahead valve 190 varies depending on the operation amount. Therefore, when the amount of operation of the travel control section 104 is small, the amount of conversion to be converted from the first position 191 of the travel straight-ahead valve 190 becomes small so that the hydraulic fluid of the third pump P3 flows into the drain line 195 The amount of the gas to be drained through the gas flow path can be gradually reduced. Accordingly, the pressure of the hydraulic fluid on the swivel parallel line 172 gradually increases, thereby preventing the swing motor 171 from suddenly being driven.

On the other hand, the signal pressure Pa5 output from the shuttle valve unit 194 is applied to the pressure receiving portion 190a through the traveling straight line 103. [ The traveling straight line signal line 103 branches to the first and second branch signal lines 103a and 103b. The first branch signal line 103a is connected to the front control valves 110, 120, 150 and 160, that is, the boom two-speed control valve 160, the arm first-speed control valve 150, (110) and the bucket control valve (120) and is connected to the drain line. The second branch signal line 103b sequentially passes through the second travel control valve 140 and the first travel control valve 100 and is connected to the drain line. In this state, any one of the front control valves 110, 120, and 150 is converted to be out of the neutral state and any one of the first and second travel control valves 100, When the control valve is converted out of the neutral state, the first and second branch signal lines 103a and 103b are disconnected from the drain line, whereby the pressure of the traveling straight line 103 can be increased.

Hereinafter, the operation of the hydraulic circuit of the construction machine having the above-described configuration will be described in detail.

FIG. 3A schematically shows a state in which the straight traveling valve 190 is converted to the second position 192. FIG. First, the operator simultaneously converts the second travel control valve 140, the arm first-speed control valve 150, and the swing control valve 170. The signal pressure Pa5 of the traveling operation unit 104 is output through the shuttle valve unit 194 and the signal pressure Pa5 output therefrom is supplied to the water pressure control valve 190 via the traveling straight line signal line 103, Is applied to the portion 190a. At this time, since the first and second branch signal lines 103a and 103b are disconnected from the drain line by the arm first-speed control valve 150 and the second travel control valve 140, The signal pressure Pa5 generated from the travel control portion 104 is directly applied to the pressure receiving portion 190a of the valve 190. [

When the driving signal pressure Pa5 is applied to the pressure receiving portion 190a of the traveling straight ahead valve 190, the straight traveling valve 190 is changed from the first position 191 to the second position 192. [ Then, the third pump P3 is connected to the first and second merging line 197 and the drain line 195 through the first to third flow paths 192a, 192b, and 192c, respectively.

3A, the operating fluid of the second pump P2 is supplied only to the second traveling motor 141, and the hydraulic fluid of the third pump P3 is supplied to the second traveling motor 141. In this case, The hydraulic oil is sequentially supplied to the arm cylinder 151 through the second merging line 197, the arm first parallel line 152, and the arm first speed control valve 150 in sequence.

The operating fluid of the third pump P3 is supplied to the swing motor 171 through the swing parallel line 172 and the swing control valve 170. [ At this time, since the hydraulic fluid discharged from the third pump P3 is drained to the drain line 195 through the third flow path 192c, the pivoting impact that the swing motor 171 is suddenly driven does not occur.

The conversion state (the state converted to the second position) of the traveling straight ahead valve 190 as shown in FIG. 3A occurs not only when the operation amount of the travel operation portion 104 is not maximum but also when the operation amount of the travel operation portion 104 is the maximum Even in the transitional state. Therefore, even when the operation amount from the travel control unit 104 is the maximum, the turning impact can be prevented.

3B is a circuit diagram schematically showing a state in which the travel straight-ahead valve 190 is switched to the third position 193 via the second position 192 when the operation amount of the travel operation unit 104 is the maximum. In this state, the third pump P3 is disconnected from the drain line 195, so that the normal driving speed of the swing motor 171 can be controlled according to the swing operation amount.

FIG. 3C is a circuit diagram schematically showing the state in which the arm 1 control valve 150 in FIG. 3A is in an untransformed neutral state and the boom first-speed control valve 110 is converted.

Referring to FIG. 3C, the first branch signal line 103a is disconnected from the drain line by the boom first-speed control valve 110. The operating fluid of the first pump P1 is supplied to the boom first-speed control valve 110 through the first running control valve 100 and the working fluid of the third pump P3 is supplied to the first joining line 196 To the boom first-speed parallel line 111 with the operating fluid of the first pump P1. In this state, the boom first-parallel line 111 is communicated with the swivel parallel line 172 through the first joining line 196 and the travel straight-line valve 190. Therefore, when a large load is applied to the boom cylinder 112 so that the pressure of the parallel line 111 of the boom 1 is larger than the pressure of the parallel line 172 of the boom, It is possible to flow back to the swivel parallel line 172 through the first-speed parallel line 111, the first joining line 196, and the traveling straight-line valve 190. Such backflow of the operating oil reduces the flow rate of the operating oil supplied to the boom cylinder 112, so that the driving speed of the boom cylinder 112 is significantly lowered. However, in this embodiment, the check valve 198 is provided to prevent reverse flow, so that the operating fluid of the first pump P1 can be supplied to the boom cylinder 112 through the boom first-speed control valve 110. [ As a result, not only the driving speed of the boom cylinder 112 can be improved, but also the turning impact can be further reduced.

4 schematically shows a hydraulic circuit of a construction machine according to another embodiment of the present invention.

Another embodiment of the present invention differs from the embodiment of the present invention in the structure of the straight traveling valve 290. That is, another embodiment of the present invention is transformed between the first position 291 and the second position 292.

The signal pressure applied to the pressure receiving portion 290a of the traveling straight-ahead valve 290 is controlled by the operation amount of the travel control portion 104 It is possible to perform linear conversion of the traveling straight ahead valve 290. [ As a result, the traveling straight ahead valve 290 can be prevented from being changed in the on / off manner as in the conventional art, thereby minimizing the turning impact. Other configurations are the same as those of the embodiment of the present invention, and therefore, detailed description thereof will be omitted.

Figs. 1A and 1B are schematic views of a conventional construction machine hydraulic circuit,

2 is a schematic view of a hydraulic circuit of a construction machine according to an embodiment of the present invention,

FIGS. 3A to 3C are views for explaining the operation of the hydraulic circuit of the construction machine shown in FIG. 2;

4 is a schematic view of a hydraulic circuit of a construction machine according to another embodiment of the present invention.

DESCRIPTION OF THE REFERENCE NUMERALS OF THE DRAWINGS

P1, P2, P3; First to third pumps 100; The first drive control valve

110; Boom first-speed control valve 120; Bucket control valve

140; A second travel control valve 150; Arm one-speed control valve

170; A swing control valve 172; Swivel parallel line

190; A straight traveling valve 190a; The hydraulic pressure portion of the traveling straight-

191, 192, 193; First to third positions 192a, 192b, 192c; The first to third euros

196; A first joining line 197; The second joining line

198; Check valve

Claims (5)

A first pump 101 for supplying operating oil to the first traveling motor 101 and the first front work machines 112 and 121 through the first traveling control valve 100 and the first front control valves 110 and 120, A second pump 151 for supplying operating fluid to the second traveling motor 141 and the second front working machine 151 through the second traveling control valve 140 and the second front control valve 150, A third pump P3 for supplying operating fluid to the swing motor 171 through the swing control valve 170 and a third pump P3 for supplying operating oil discharged from the third pump P3 to the first front control valve 110 A first merging line 196 for merging the hydraulic fluid of the third pump P3 with the hydraulic fluid of the first pump P1 at a front end of the second front control valve 150, A second merging line 197 for merging the working oil of the second pump P2 with the working fluid of the second pump P2, In the hydraulic circuit for a construction machine that includes a line 195, (190a) to which the signal pressures (Pa4), (Pb4), (Pa5) and (Pb5) are applied, and the pressure receiving portions A straight running valve 190 that changes the first to third positions 191, 192, and 193 according to the magnitude of the signal pressure Pa4 (Pb4) (Pa5) (Pb5) And And a swivel parallel line (172) for bypassing the running straight valve (190) and supplying the operating fluid of the third pump (P3) to the swivel control valve (170) The third pump P3 and the drain line 195 are communicated with the first displacement amount and the third pump P3 and the drain line 195 are communicated with each other by the first displacement amount when the traveling rectilinear valve 190 is converted into the first position 191, The connection of the first and second merging lines 196 and 197 is blocked, The third pump P3 is communicated with the first merging line 196 through the first flow path 192a and the third pump P3 is communicated with the second merging line 196 via the first flow path 192a, The third pump P3 is communicated with the second merging line 197 through the third passage 192b and the third pump P3 is communicated with the second merging line 197 through the third passage 192c, And is communicated with the drain line 195 in a predetermined amount, The third pump P3 is in communication with each of the first and second merging lines 196 and 197 and the third pump P3 is connected to the third pump 193, P3) and the drain line (195) are cut off. The method according to claim 1, A large signal pressure out of the traveling signal pressures Pa4, Pb4, Pa5, and Pb5 applied to the first and second traveling control valves 100 and 140 is transmitted to the traveling straight line through the traveling straight line signal line 103 Further comprising a shuttle valve unit (194) for applying pressure to the pressure receiving portion (190a) of the valve (190). 3. The method of claim 2, A first branch signal line 103a branching from the traveling straight line 103 and sequentially passing through the first and second travel control valves 100 and 140 to be connected to the drain line; And a second branch signal line 103b connected to the drain line through the first and second front control valves 110, 120 and 150, respectively, When at least one of the first and second travel control valves 100 and 140 is out of the neutral state and at least one of the first and second front control valves 110, 120, and 150 is in a neutral state , The first and second branch signal lines (103a) and (103b) are disconnected from the drain line. The method according to claim 1, The third pump P3 and the traveling straight-ahead valve (not shown) are provided so that the hydraulic fluid discharged from the first pump P1 can be prevented from flowing back to the swivel parallel line 172 through the first merging line 196, 190), and further comprising a check valve (198). A first pump 101 for supplying operating oil to the first traveling motor 101 and the first front work machines 112 and 121 through the first traveling control valve 100 and the first front control valves 110 and 120, And a second pump for supplying operating fluid to the second traveling motor 141 and the second front work machine 151 through the second traveling control valve 140 and the second front control valve 150, A third pump P3 for supplying operating fluid to the swing motor 171 through the swing control valve 170 and a third pump P3 for supplying operating oil discharged from the third pump P3 to the first front control valve 110) 120 and a working fluid of the third pump (P3) from the front end of the second front work machine (151), and a second joining line A second merging line 197 for merging the working fluid of the third pump P3 with the working fluid of the second pump P2 and a drain for draining the working fluid of the third pump P3 through the swing control valve 170. [ In a hydraulic circuit of a construction machine comprising an in line (195)  (Pb4) (Pa5) (Pb5) to which the signal pressure Pa4 (Pb4) (Pa5) (Pb5) is applied and the signal pressures Pa4 A straight running valve 290 for converting between the first position 291 and the second position 292 depending on the size; A swivel parallel line 172 that bypasses the traveling straight ahead valve 290 and connects the third pump P3 and the swing control valve 170; And A large signal pressure among the traveling signal pressures Pa4, Pb4, Pa5, and Pb5 applied to the first and second travel control valves 100 and 140 is applied to the hydraulic pressure portion of the traveling straight line valve 290 And a shuttle valve unit (194) The third pump P3 is communicated with the drain line 195 and the third pump P3 and the first and second pumps P3 and P3 are communicated with each other when the traveling straight ahead valve 290 is converted into the first position 291. [ The connection of the confluent lines 196 and 197 is shut off, The third pump P3 is in communication with each of the first and second merging lines 196 and 197 and the third pump P3 is communicated with the third pump P3 when the forward straight ahead valve 290 is converted to the second position 292. [ (P3) is disconnected from the drain line (195).

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