CN213679680U - Energy recovery system based on multi-hydraulic motor-accumulator combined electric forklift - Google Patents

Abstract

The utility model discloses an energy recovery system based on multi-hydraulic motor-accumulator combination electric fork truck, which comprises a control unit, a main hydraulic cylinder, an accumulator, a storage battery and two hydraulic motor-generator units, wherein the main hydraulic cylinder, the accumulator, the storage battery and the two hydraulic motor-generator units are connected into a main hydraulic circuit; the control unit comprises a complete machine controller which is used for calculating a target rotating speed according to a handle signal of the electric control handle and judging the current load interval of the electric forklift through the pressure of a rodless cavity on the main hydraulic cylinder so as to control the on-off of each reversing valve according to the load interval when the load descends; and controlling the rotating speed of the generator in the corresponding hydraulic motor/generator unit according to the target rotating speed output by the complete machine controller. During the load descending process, the energy recovery requirements of different load sizes from no load to full load are met.

Description

Energy recovery system based on multi-hydraulic motor-accumulator combined electric forklift

Technical Field

The utility model relates to an electric fork-lift, more specifically say and relate to an energy recuperation system based on many hydraulic motor-accumulator combination electric fork-lift.

Background

The electric forklift is used as main carrying equipment for warehouse logistics, generally needs to perform reciprocating lifting action under the load of several tons to dozens of tons, the lifting height range is wide, so that the goods are always provided with larger load gravitational potential energy when descending, and the load gravitational potential energy of the part is mainly dissipated at a throttling opening in the form of heat energy. However, in the analysis of the energy consumption of the whole electric forklift, the energy consumption of the lifting system of the electric forklift accounts for more than 40% of the energy consumption of the whole electric forklift, so that the potential energy of the load can be effectively recovered, the waste of the potential energy of the load can be avoided, and the energy consumption is reduced by recovering and utilizing the potential energy of the load, and at present, research is mainly carried out around a hydraulic method and an electric method.

The hydraulic energy recovery mainly adopts a hydraulic energy accumulator to recover gravitational potential energy, but because the pressure of the hydraulic energy accumulator is gradually increased in the recovery process, the energy accumulator with larger capacity is generally selected in order not to influence the normal downward transfer of the electric forklift. However, for heavy-duty forklifts, the gravitational potential energy is high, so the required energy accumulator is large in size and not suitable for installation, and is not suitable for being used as an energy storage device independently.

The electric energy recovery mainly adopts a hydraulic motor to drive a generator to output electric energy so as to convert gravitational potential energy into electric energy for storage, and generally adopts a single fixed displacement hydraulic motor to drive the generator to realize the recovery of the gravitational potential energy, so that under the working condition of small load, the heavy forklift with a large load change interval can cause extra energy loss and has low working efficiency; moreover, for a heavy forklift with high gravitational potential energy, a single large-displacement hydraulic motor and a high-power generator are adopted, energy recovery can be realized, but the requirements on the generator and a motor controller are high, the cost is improved, the reliability is low, particularly, under the condition of heavy load and low speed, the generator is in a low-efficiency area, and the energy recovery efficiency is low. For example, the load acting on the lifting cylinder of a heavy electric forklift is between 5 and 30 tons, and the load change ratio can reach about 6 times at most in one working cycle from no load to full load; if the energy is recovered when the vehicle is fully loaded, a single large-displacement hydraulic motor and a single high-power generator are adopted for energy recovery, and the phenomenon of large material and small material consumption when the vehicle is in no load or in small load is caused; when the load is small, the recoverable power is low, at the moment, the hydraulic motor is in a low-rotating-speed interval, and the generator works in a low-efficiency area, so that the recovery efficiency is low; similarly, when the load is reduced at low speed, the generator also enters a low-efficiency area; therefore, the large displacement hydraulic motor limits the minimum lowering speed and the minimum load of the system, and has narrow economic applicability. If a small-displacement hydraulic motor is adopted, the hydraulic motor is obviously not suitable for a large load, and load gravitational potential energy loss still exists in the large load.

SUMMERY OF THE UTILITY MODEL

The utility model aims at providing an energy recuperation system based on many hydraulic motor-accumulator combination electric fork-lift, between the use of rational distribution energy storage ware and motor, both be applicable to heavy electric fork-lift from empty load to the energy recuperation demand of the big inter-regional variation range of full-load, restriction when effectively solving single big displacement motor and high-power generator and receiving little load and minimum decline speed improves energy recuperation efficiency.

In order to achieve the above purpose, the utility model discloses a solution is:

an energy recovery system based on a multi-hydraulic motor-accumulator combined electric forklift comprises a main hydraulic cylinder, an accumulator, a storage battery, two hydraulic motor-generator units and an electric control handle with different gears, wherein the main hydraulic cylinder, the accumulator, the storage battery and the two hydraulic motor-generator units are respectively connected into a main hydraulic circuit of the electric forklift, a plurality of reversing valves are respectively installed on the main hydraulic circuit, and the main hydraulic cylinder controls the on-off between the main hydraulic cylinder and the accumulator and between the main hydraulic motor-generator units through the on-off of each reversing valve;

the control unit comprises a complete machine controller which is used for calculating a target rotating speed according to a handle signal transmitted by the electric control handle and judging the current load interval of the electric forklift through the pressure of a rodless cavity on the main hydraulic cylinder so as to control the on-off of each reversing valve according to the load interval in the load descending process; the control unit also comprises a motor controller which controls the rotating speed of the generator in the hydraulic motor/generator unit according to the target rotating speed output by the complete machine controller.

The two hydraulic motor-generator units are respectively provided with the motor controller, and correspond to a first hydraulic motor-generator unit and a second hydraulic motor-generator unit respectively;

the first hydraulic motor-generator unit comprises a first motor and a first generator, an output shaft of the first motor is in transmission connection with a rotating shaft of the first generator, the motor controller paired with the first motor is a first motor controller, and the first motor controller is coaxially connected with the first generator; the second hydraulic motor-generator unit comprises a second motor and a second generator, an output shaft of the second motor is in transmission connection with a rotating shaft of the second generator, the motor controller paired with the second motor is a second motor controller, and the second motor controller is coaxially connected with the second generator;

the signal output end of the complete machine controller is respectively and electrically connected with the signal input ends of the first motor controller and the second motor controller, the power supply ends of the first motor controller and the second motor controller are both connected with the power supply end of the storage battery, and the signal output end of the electric control handle is electrically connected with the signal input end of the complete machine controller.

The reversing valves are respectively and correspondingly a three-position six-way proportional reversing valve, a two-position two-way first electromagnetic reversing valve, a two-position two-way second electromagnetic reversing valve and a two-position two-way fourth electromagnetic reversing valve, a two-position three-way third electromagnetic reversing valve and a two-position two-way first hydraulic control reversing valve and a two-position two-way second hydraulic control reversing valve.

The rod cavity of the master hydraulic cylinder is connected with an oil tank, the rodless cavity of the master hydraulic cylinder is connected with the port A of the proportional reversing valve, the port C of the proportional reversing valve is connected with the oil tank, the port T2 of the proportional reversing valve is respectively connected with the port P of the first hydraulic control reversing valve, the port P of the second hydraulic control reversing valve and the port P of the fourth electromagnetic reversing valve, the port A of the fourth electromagnetic reversing valve is connected with the oil tank, the port A of the first hydraulic control reversing valve is connected with the hydraulic control energy accumulator, the port A of the second hydraulic control reversing valve is connected with the oil tank through a third one-way valve, a branch is arranged at a collection node between the port A of the second hydraulic control reversing valve and the oil outlet of the third one-way valve and is respectively connected with the ports P of the first electromagnetic reversing valve and the second electromagnetic reversing valve, and the right port D1 of the first hydraulic control reversing valve and the right port D2 of the second hydraulic control reversing valve are respectively connected with the port A of the third electromagnetic reversing valve, the T port of the third electromagnetic reversing valve, the left hydraulic control port of the first hydraulic control reversing valve and the left hydraulic control port of the second hydraulic control reversing valve are connected with an oil tank; the port A of the first electromagnetic directional valve is connected with the oil inlet of the first motor, the port A of the second electromagnetic directional valve is connected with the oil inlet of the second motor, and the oil outlets of the first motor and the second motor are both connected with an oil tank.

The hydraulic pump system further comprises a driving unit, wherein the driving unit comprises a motor, a main hydraulic pump and a pilot hydraulic pump, the pilot hydraulic pump is coaxially connected with the motor, and the pilot hydraulic pump is coaxially connected with the main hydraulic pump; and the oil inlets of the main hydraulic pump and the pilot hydraulic pump are both connected with an oil tank, the oil outlet of the main hydraulic pump is connected with the oil inlet of a first one-way valve, the oil outlet of the first one-way valve is divided into two paths, one path is connected with a T1 port of the proportional reversing valve, the other path is connected with a P port of the proportional reversing valve through a second one-way valve, and the oil outlet of the pilot hydraulic pump is connected with a P port of a third electromagnetic reversing valve through a fourth one-way valve.

The control unit further comprises a plurality of pressure sensors, each pressure sensor corresponds to a first pressure sensor, a second pressure sensor, a third pressure sensor and a fourth pressure sensor, the first pressure sensor is installed at the position of the rodless cavity of the master cylinder, the second pressure sensor is installed at the position of an inlet and an outlet of the energy accumulator, the third pressure sensor is installed at the position of an oil inlet of the first motor, and the fourth pressure sensor is installed at the position of an oil inlet of the second motor;

the signal output ends of the first pressure sensor, the second pressure sensor, the third pressure sensor and the fourth pressure sensor are respectively and electrically connected with the signal input end of the complete machine controller.

The load interval is preset in the complete machine controller and is divided into a first gear, a second gear, a third gear, a fourth gear and a fifth gear; the first gear corresponds to energy recovery of an energy accumulator, the second gear corresponds to energy recovery of a first hydraulic motor-generator unit, the third gear corresponds to energy recovery of a second hydraulic motor-generator unit, the fourth gear corresponds to joint energy recovery of two hydraulic motor-generator units, and the fifth gear corresponds to joint energy recovery of the energy accumulator and the two hydraulic motor-generator units.

The first gear is p_L≤p_min，p_LData collected for the first pressure sensor, p_minA minimum load pressure for the hydraulic motor-generator unit that produces no additional losses;

the second gear is p_min≤p_L≤p_dAnd SOC of the storage battery is less than S_max，p_dIs the maximum load value of the second gear load interval, S_maxThe maximum allowable electric quantity value of the storage battery;

the third gear is p_d≤p_L≤p_eAnd SOC of the storage battery is less than S_max，p_eThe load is the maximum value of the load interval of the third gear;

the fourth gear is p_e≤p_L≤p_rAnd SOC of the storage battery is less than S_max，p_rThe load is the maximum value of the load interval of the fourth gear;

the fifth gear is p_r≤p_L≤p_LmaxAnd SOC of the storage battery is less than S_max，p_rThe load is the maximum value of the load interval of the fifth gear.

After the structure is adopted, the utility model discloses following beneficial effect has: the energy accumulator and the two hydraulic motor-generator units are arranged, the whole machine controller judges the current load interval according to the pressure of the rodless cavity in the main hydraulic cylinder, controls the on-off of each reversing valve to switch to a proper hydraulic path to select the optimal energy recovery mode, determines the target rotating speed of the generators in the two hydraulic motor-generator units according to the received handle signal of the electric control handle to change the load reduction speed into volume speed regulation, can obtain more optimal load reduction speed control while achieving energy recovery, reasonably distributes the use intervals of the energy accumulator and the two hydraulic motor-generator units, enlarges the load adaptation range of the electric forklift, meets the energy recovery requirements of different load sizes from no load to full load, effectively solves the problems that the energy recovery of the energy accumulator is limited and the single large-displacement hydraulic motor and the large-power generator are limited when the load is small and the minimum reduction speed, the energy recovery efficiency is improved.

Drawings

Fig. 1 is a schematic connection diagram of the present invention.

In the figure:

100-an electric control handle; 10-a first hydraulic cylinder;

11-a second hydraulic cylinder; 12-an accumulator;

13-a storage battery; 21-a complete machine controller;

31-a first motor; 32-a first generator;

33-a first motor controller; 41-a second motor;

42-a second generator; 43-a second motor controller;

51-a first pressure sensor; 52-a second pressure sensor;

53-a third pressure sensor; 54-a fourth pressure sensor;

60-proportional reversing valves; 61-a first electromagnetic directional valve;

62-a second electromagnetic directional valve; 63-a third electromagnetic directional valve;

64-a first pilot operated directional control valve; 65-a second hydraulically controlled directional control valve;

66-a fourth electromagnetic directional valve; 71-an electric motor;

72-main hydraulic pump; 73-a third motor controller;

74-a pilot hydraulic pump; 81-a first one-way valve;

82-a second one-way valve; 83-a third one-way valve;

84-fourth one-way valve.

Detailed Description

In order to further explain the technical solution of the present invention, the present invention is explained in detail by the following embodiments.

An energy recovery system based on a multi-hydraulic motor-accumulator electric forklift is suitable for conventional electric forklifts, such as heavy electric forklifts.

As shown in fig. 1, the energy recovery system includes a master cylinder, an accumulator 12, a storage battery 13, two hydraulic motor-generator units and an electric control handle 100 with different gears, the storage battery 13 is used for storing electric energy converted by the two hydraulic motor-generator units, the two hydraulic motor-generator units are respectively adapted to different load levels, the master cylinder, the accumulator 12 and the two hydraulic motor-generator units are respectively connected to the master cylinder, the two hydraulic motor-generator units are respectively corresponding to a first hydraulic motor-generator unit and a second hydraulic motor-generator unit, a plurality of reversing valves are respectively installed on a main hydraulic circuit, and the main hydraulic circuit is connected and disconnected between the energy accumulator 10 and a main hydraulic cylinder, between the first hydraulic motor-generator unit and the main hydraulic cylinder and between the second hydraulic motor-generator unit and the main hydraulic cylinder through the connection and disconnection of all the reversing valves.

In the present invention, the accumulator 12 is a known hydraulic accumulator.

In this embodiment, the master cylinder includes a first cylinder 10 and a second cylinder 12, the first cylinder 10 and the second cylinder 11 being rigidly connected in a conventional manner, and the master cylinder is a well-known cylinder.

In this embodiment, five gears of the electric control handle are taken as an example for explanation, and the signal input end of the complete machine controller 21 is connected to each signal output end of the electric control handle, so as to transmit a handle signal of the electric control handle to the signal input end of the complete machine controller 21.

The utility model discloses still include the control unit, the control unit includes complete machine controller 21, machine controller and a plurality of pressure sensor, complete machine controller 21 is used for calculating target rotational speed through handle signal to and the load interval of judging current electric fork-lift truck through the pressure in no pole chamber on the main hydraulic cylinder, in the break-make of the in-process in order to select each switching-over valve of control according to the load interval that descends. The motor controller is used for respectively controlling the rotating speed of the generators in the two hydraulic motor-generator units according to the target rotating speed output by the complete machine controller, and each pressure sensor is arranged in the main hydraulic cylinder and respectively arranged at the rodless cavity of the main hydraulic cylinder, the inlet and the outlet of the energy accumulator 13 and the inlet and the outlet of the two hydraulic motor-generator units.

In the present invention, the overall controller 21 is a known controller, such as a controller with a model number of TTC 60.

In the present embodiment, the pressure sensors correspond to a first pressure sensor 51, a second pressure sensor 52, a third pressure sensor 53, and a fourth pressure sensor 54, respectively. The pressure sensor located in the rodless cavity of the master cylinder corresponds to a first pressure sensor 51, the pressure sensor located at the inlet and outlet of the accumulator 13 is a second pressure sensor 52, and the pressure sensors located at the inlet and outlet of the two hydraulic motor-generator units are a third pressure sensor 53 and a fourth pressure sensor 54, respectively. The signal output end of each pressure sensor is electrically connected to the signal input end of the complete machine controller 21, so as to transmit the pressure information acquired by each pressure sensor to the complete machine controller 21.

In the present invention, two hydraulic motor-generator units are respectively provided with a motor controller, in this embodiment, two motor controllers are taken as an example for explanation, the first hydraulic motor-generator unit includes the first motor 31 and the first generator 32, accordingly, the paired motor controller of the first generator 32 is the first motor controller 33, the first motor controller 33 is coaxially connected with the first generator 32, the output shaft of the first motor 31 is in transmission connection with the rotating shaft of the first generator 32, and the connection structure between them is the prior known technology, such as the coupling connection between them. The second hydraulic motor-generator unit comprises a second motor 41 and a second generator 42, wherein a paired motor controller of the second generator 42 is a second motor controller 43, the second motor controller 43 is coaxially connected with the second generator 42, and an output shaft of the second motor 41 is in transmission connection with a rotating shaft of the second generator 42. In this embodiment, the first motor controller 33 and the second motor controller 43 are both known motor controllers, such as the 4D90 motor controller of ABM.

The signal output end of the complete machine controller 21 is respectively connected with the signal input ends of the first motor controller 33 and the second motor controller 43, the power supply end of the first generator 32 is connected with the power supply end of the first motor controller 33, the power supply end of the second generator 42 is electrically connected with the power supply end of the second motor controller, and the power supply output ends of the first motor controller 33 and the second motor controller 43 are electrically connected with the power supply input end of the storage battery 13.

In the embodiment, the first hydraulic motor-generator unit is adapted to a small-load working condition, and the second hydraulic motor-generator unit is adapted to a medium-load working condition, wherein the interval division of the load size is manually set by combining with an actual condition. The specific process is as follows:

1. when the load is small in the descending process, the two hydraulic motor-generator units are adopted to cause extra loss, so that the gravitational potential energy enters the energy accumulator 12 to be recovered by the energy accumulator;

2. when the load is smaller and larger than the critical load of the first hydraulic motor-generator unit generating extra loss in the descending process, the complete machine controller 21 selects the first hydraulic motor-generator unit as an energy recovery unit, and the complete machine controller 21 acquires the target rotating speed of the first motor 31 according to the handle signal of the electric control handle 100 to enable the first generator 31 to work in a high-efficiency area;

3. when the load is in a medium tonnage in the descending process, a second hydraulic motor-generator unit is used as an energy recovery unit, and the complete machine controller 21 acquires the target rotating speed of the second motor 41 according to a handle signal of the electric control handle 100 so as to enable the second generator 42 to work in a high-efficiency area;

4. when the descent process is under a heavy-load working condition, the first hydraulic motor-generator unit and the second hydraulic motor-generator unit are jointly used for energy recovery, and the complete machine controller 21 respectively obtains the target rotating speeds of the first motor 31 and the second motor 41 according to a handle signal of the electric control handle 100 so as to meet the energy recovery requirement;

5. under the full-load working condition, the energy accumulator 12 is adopted to recover partial gravitational potential energy, and when the energy accumulator 12 achieves the maximum energy recovery, the combined use of the first hydraulic motor-generator unit and the second hydraulic motor-generator unit is switched to carry out energy recovery.

For example, if the full load of the heavy-duty electric forklift is 30t, the heavy-duty electric forklift can be distributed according to the mode of 5t +8t +17t, namely the load is within 5t (including 5t), and the accumulator 12 is used for recovering the gravitational potential energy; if the load is between 5t and 8t (not including 5t, but including 8t), adopting a first hydraulic motor-generator unit to recover gravitational potential energy; if the load is between 8t and 17t (excluding 8t but including 17t), the second hydraulic motor-generator unit is used for gravitational potential energy recovery. For example, if the load is 4t, the energy accumulator 12 is adopted to recover the gravitational potential energy; similarly, when the load is 25t, the energy recovery is performed simultaneously using the first hydraulic motor-generator unit and the second hydraulic motor-generator unit in combination.

It should be noted that the two hydraulic motors use different displacement volumes and the two generators use different powers, even though the two hydraulic motor-generator units are adapted to different load classes.

The utility model discloses still include drive unit, drive unit includes motor 71, main hydraulic pump 72 and guide's hydraulic pump 74, motor 71 and guide's hydraulic pump 74 coaxial coupling, guide's hydraulic pump 74 and main hydraulic pump 72 coaxial coupling, wherein, main hydraulic pump 72 controls the break-make of each switching-over valve in order to realize with the break-make of main hydraulic cylinder through complete machine controller 31. The control unit further comprises a third motor controller 73. The power supply input end of the third motor controller 73 is connected with the power supply output end of the storage battery 13, the torque output end of the third motor controller 73 is connected with the signal input end of the motor 71, and the third motor controller 73 is bidirectionally connected with the whole machine controller 21.

The utility model discloses in, each switching-over valve corresponds respectively to be proportional reversing valve 60, first solenoid directional valve 61, second solenoid directional valve 62, third solenoid directional valve 63, first liquid accuse switching-over valve 64, second liquid accuse switching-over valve 65 and fourth solenoid directional valve 66. The proportional directional valve 60 is a known three-position six-way proportional directional valve, the first electromagnetic directional valve 61, the second electromagnetic directional valve 62 and the fourth electromagnetic directional valve 66 are all known two-position two-way electromagnetic directional valves, the third electromagnetic directional valve 63 is a known two-position three-way electromagnetic directional valve, and the first hydraulic control directional valve 64 and the second hydraulic control directional valve 65 are all known two-position two-way hydraulic control directional valves. Wherein, the signal input ends of the proportional directional valve 60, the first electromagnetic directional valve 61, the second electromagnetic directional valve 62, the third electromagnetic directional valve 63 and the fourth electromagnetic directional valve 66 are respectively connected with the signal output end of the complete machine controller 21.

The specific connection structure of the main liquid path is as follows: an oil inlet of the main hydraulic pump 72 is connected with an oil tank, an oil outlet of the main hydraulic pump 72 is connected with an oil inlet of a first one-way valve 81, an oil outlet of the first one-way valve 81 is divided into two paths, one path is connected with a T1 port of the proportional reversing valve 60, the other path is connected with a P port of the proportional reversing valve 60 through a second one-way valve 82, an A port of the proportional reversing valve 60 is respectively connected with rodless cavities of the first hydraulic cylinder 10 and the second hydraulic cylinder 11, and rod cavities of the first hydraulic cylinder 10 and the second hydraulic cylinder 11 are both connected with the oil tank; a port T2 of the proportional reversing valve 60 is respectively connected with ports P of a first hydraulic control reversing valve 64, a second hydraulic control reversing valve 65 and a fourth electromagnetic reversing valve 66, a port A of the first hydraulic control reversing valve 64 is connected with the energy accumulator 12 through a ball valve, a port A of the second hydraulic control reversing valve 65 is connected with an oil outlet of a third one-way valve 83, an oil inlet of the third one-way valve 83 is connected with an oil tank, a branch is branched at a collection node between the port A of the second hydraulic control reversing valve 65 and the third one-way valve 83 and is respectively connected with the port P of the first electromagnetic reversing valve 61 and the port P of the second electromagnetic reversing valve 62, a port D1 on the right side of the first hydraulic control reversing valve 64 and a port D2 on the right side of the second hydraulic control reversing valve 65 are respectively connected with the port A of the third electromagnetic reversing valve 63, a port T of the third electromagnetic reversing valve 63, a port left side of the first hydraulic control reversing valve 64 and a port left side of the second hydraulic control reversing valve 65 are respectively connected with the oil, the port A of the fourth electromagnetic directional valve 66 is connected with the oil tank, and the port P of the third electromagnetic directional valve 63 is connected with the oil outlet of the pilot hydraulic pump 74 through a fourth one-way valve 84; the port A of the first electromagnetic directional valve 61 is connected with the oil inlet of the first motor 31, the oil outlet of the first motor 31 is connected with the oil tank, the end A of the second electromagnetic directional valve 62 is connected with the oil inlet of the second motor 41, and the oil outlet of the second motor 41 is connected with the oil tank; wherein, the port C of the proportional directional valve 60 is connected with the oil tank.

Preferably, a first overflow valve is further conventionally connected to the oil outlet of the fourth check valve 84, and an outlet end of the first overflow valve is connected to the oil tank.

Preferably, a second relief valve is further mounted at the oil inlet of the first motor 31 in a conventional manner, and an outlet end of the second relief valve is connected with the oil tank; and a third relief valve is further mounted at the oil inlet of the second motor 41 in a conventional manner, and the outlet end of the third relief valve is connected with an oil tank.

In this embodiment, the first pressure sensor 51 is installed at the port a of the proportional directional valve 60 to obtain the pressure of the rodless cavity of the master cylinder, and the pressure signal collected by the first pressure sensor 51 is denoted as p_L(ii) a The second pressure sensor 52 is installed between the ball valve and the port a of the first pilot-controlled directional valve 64 to obtain the inlet pressure of the accumulator, and the pressure signal collected by the second pressure sensor 52 is recorded as p₁(ii) a The third pressure sensor 53 is installed between the port a of the first electromagnetic directional valve 61 and the oil inlet of the first motor 31 to obtain the pressure at the inlet of the first motor 31, and the pressure signal collected by the third pressure sensor 53 is recorded as p₂(ii) a The fourth pressure sensor 54 is installed between the port a of the second electromagnetic directional valve 62 and the oil inlet of the second motor 41 to obtain the pressure at the inlet of the second motor 41, and the pressure signal collected by the fourth pressure sensor 54 is denoted as p₃。

An energy recovery system based on a multi-hydraulic motor-accumulator electric forklift divides the load into a plurality of load intervals and stores the load intervals in a complete machine controller 21, and the complete machine controller 21 stores the load intervals in the complete machine controller 21 according to the pressure P of a rodless cavity in a main hydraulic cylinder_LJudging the load interval of the current load, controlling the on-off of each reversing valve to select a proper liquid path, and actively controlling the target rotating speed and the recovery power of the first generator and the second generator according to the received handle signal of the electric control handle by taking the load descending speed requirement and the recovery power requirement as the target, wherein the specific working process is as follows.

The overall controller 21 has a storage unit for presetting a load interval, in this embodiment, the load interval is divided into five steps, each load interval is divided into a first step, a second step, a third step, a fourth step and a fifth step, wherein the division of each load interval is preset according to circumstances, and is not limited to the above division.

First, when the load rises, the solenoid DT1 of the proportional directional valve 60 is de-energized, the solenoid DT2 of the proportional directional valve 60 is energized, and the high-pressure oil output from the main hydraulic pump 72 drives the main hydraulic cylinder to extend through the right position of the proportional directional valve 60, which is the side close to the solenoid DT2 of the proportional directional valve 60 as shown in fig. 1, so as to raise the load.

When the load is reduced, the electromagnet DT1 of the proportional directional valve 60 is electrified, the electromagnet DT2 of the proportional directional valve 60 is electrified, the main hydraulic pump 72 is unloaded, and the high-pressure oil of the rodless cavity of the main hydraulic cylinder enters the main hydraulic circuit through the T2 port of the proportional directional valve 60 for gravitational potential energy recovery, which specifically comprises the following steps:

A. first gear energy accumulator energy recovery

When the controller judges the load pressure p_L≤p_minWhen the power of the electromagnet DT3 of the third electromagnetic directional valve 63 is lost, the first hydraulic control directional valve 64 is turned on, and the descending potential energy of the load enters the energy accumulator 12 through the T2 port of the proportional directional valve 60 and the a port of the first hydraulic control directional valve 64 in sequence for recovery. Wherein the recovered gravitational potential energy satisfies P₁×t₁＝E_LAnd the recovered gravitational potential energy can be used for assisting other small loads (namely the small load is less than or equal to p) of the electric forklift in the next working cycle_min) The actuator operates.

When the complete machine controller judges the inlet pressure p of the energy accumulator₁≥p_1maxAnd when the pressure of the hydraulic cylinder reaches the preset pressure, the energy accumulator 12 is controlled to stop recovering the gravity potential energy, the electromagnet DT6 of the fourth electromagnetic directional valve 66 is electrified, and the high-pressure oil of the rodless cavity of the main hydraulic cylinder flows into the oil tank through the T2 port of the proportional directional valve 60 and the A port of the fourth electromagnetic directional valve 66 in sequence.

Note that, p is_minMinimum load pressure, p, for the hydraulic motor-generator unit without additional losses_1maxThe maximum recovery pressure allowed for the accumulator 12, t₁The accumulator recovery time; p₁For the power recovered by the accumulator 12, the power recovered by the accumulator 12 is obtained by installing a conventional flow meter between the first pilot operated directional control valve 64 and the accumulator 12 to obtain the flow rate, so that the whole machine controller 31 can obtain the flow rate according to the inlet pressure and the flow rateCalculating the recovery power of the energy accumulator; e_LIs a recoverable energy. Wherein p is_minAnd p_1maxThe data are manually set according to actual conditions respectively, t₁The data can be acquired in a conventional manner, such as by a timer, and transmitted to the overall machine controller.

B. Second gear-first hydraulic motor-generator unit energy recovery

When the complete machine controller judges p_min≤p_L≤p_dAnd SOC of the storage battery is less than S_maxWhen the hydraulic motor is started, the electromagnet DT3 of the third electromagnetic directional valve 63 is controlled to be electrified, the electromagnet DT4 of the first electromagnetic directional valve 61 is controlled to be electrified, so that the high-pressure oil in the rodless cavity of the main hydraulic cylinder enters the oil inlet of the first motor 31 through the T2 port of the proportional directional valve 60, the A port of the second hydraulic directional valve 65 and the A port of the first electromagnetic directional valve 61 in sequence, at the moment, the first hydraulic directional valve 64 is in the open circuit state, the gravitational potential energy is converted into electric energy through the first generator 32, and the electric energy is stored in the storage battery 13.

The torque of the first motor 31 is

The whole machine controller 21 obtains a target rotating speed of the first generator according to the handle signal output by the electric control handle 100, wherein the target rotating speed is n₁＝[k₁(Y_p-Y₁)+n₀₁]s, recovered power P₂＝T₁×2πn₁＝p₂V₁[k₁(Y_p-Y₁)+n₀₁]s, the recovered energy satisfies P₂×t₂＝E_L。

Along with the reduction of the load, the SOC of the storage battery is gradually increased, and when the complete machine controller judges that the SOC of the storage battery is more than or equal to S_maxWhen the energy accumulator 12 recovers gravitational potential energy, the electromagnet DT3 of the third electromagnetic directional valve 63 is controlled to be powered off, the electromagnet DT4 of the first electromagnetic directional valve 61 is controlled to be powered off, so that the first hydraulic control directional valve 64 is in a communicated state, and the recovered gravitational potential energy satisfies P₁×t₁+P₂×t₂＝E_L. When the controller judges the inlet pressure of the energy accumulatorForce p₁≥p_1maxAnd when the pressure of the hydraulic cylinder reaches the preset pressure, the energy accumulator 12 is controlled to stop recovering the gravity potential energy, the electromagnet DT6 of the fourth electromagnetic directional valve 66 is electrified, and the high-pressure oil of the rodless cavity of the main hydraulic cylinder flows into the oil tank through the T2 port of the proportional directional valve 60 and the A port of the fourth electromagnetic directional valve 66 in sequence.

Note that, p is_dIs the maximum load value of the second gear load interval, S_maxThe maximum allowable electric quantity value for the battery 13; yp is the signal size of the electric control handle, namely the current pulling displacement of the electric control handle, and is reflected as a handle voltage signal of the electric control handle; y is₁Is a handle voltage signal dead zone of the electric control handle; n is₀₁The lowest operating speed of the first generator 32; k is a radical of₁Is the proportional relationship between the target speed of the first generator 32 and the handle signal; s is the SOC state characterization quantity of the storage battery 13, and when SOC is less than S_maxWhen S is 1, SOC is more than or equal to S_maxWhen s is 0; v₁Is the displacement of the first motor 31; t is t₂Is the first hydraulic motor-generator unit recovery time; p₂Recovering power for the first hydraulic motor-generator unit.

C. Third gear-second hydraulic motor-generator unit energy recovery

When the complete machine controller judges p_d≤p_L≤p_eAnd SOC of the storage battery is less than S_maxWhen the hydraulic motor is used, the electromagnet DT3 of the third electromagnetic directional valve 63 and the electromagnet DT5 of the second electromagnetic directional valve 62 are respectively controlled to be powered on, so that high-pressure oil in a rodless cavity in the main hydraulic cylinder sequentially enters an oil inlet of the second motor 41 through the proportional directional valve T2, the port A of the second hydraulic directional valve 65 and the port A of the second electromagnetic directional valve 62, and gravitational potential energy is converted into electric energy through the second generator 42 and stored in the storage battery 13.

The second hydraulic motor has a torque of

In order to meet the load reduction speed requirement and the power recovery requirement, the complete machine controller obtains a target rotating speed of the second generator 42 according to a handle signal of the electric control handle, wherein the target rotating speed is n₂＝[k₂(Y_p-Y₁)+n₀₂]s, recovered power P₃＝T₂×2πn₂＝p₃V₂[k₂(Y_p-Y₁)+n₀₂]s, the recovered energy satisfies P₃×t₃＝E_L。

Along with the reduction of the load, the SOC of the storage battery is gradually increased, and when the complete machine controller judges that the SOC of the storage battery is more than or equal to S_maxWhen the gravity potential energy is recovered, the electromagnet DT3 of the third electromagnetic reversing valve 63 is controlled to be powered off, the electromagnet DT5 of the second electromagnetic reversing valve 62 is controlled to be powered off, so that the first hydraulic control reversing valve 64 is powered on, the energy accumulator 12 recovers the gravity potential energy, and the recovered gravity potential energy meets the requirement of P₁×t₁+P₃×t₃＝E_L. When the complete machine controller judges the inlet pressure p of the energy accumulator₁≥p_1maxAnd when the pressure of the hydraulic cylinder reaches the preset pressure, the energy accumulator 12 is controlled to stop recovering the gravity potential energy, the electromagnet DT6 of the fourth electromagnetic directional valve 66 is electrified, and the high-pressure oil of the rodless cavity of the main hydraulic cylinder flows into the oil tank through the T2 port of the proportional directional valve 60 and the A port of the fourth electromagnetic directional valve 66 in sequence.

Note that, p is_eThe load is the maximum value of the load interval of the third gear; n is₀₂Is the lowest operating speed of the second generator 42; k is a radical of₂Is the proportional relationship of the target rotation speed of the second generator 42 to the handle signal; v₂Is the displacement of the second motor 41; t is t₃Is the first hydraulic motor-generator unit recovery time; p₃Recovering power for the second hydraulic motor-generator unit.

D. Simultaneous energy recovery of a fourth gear-two hydraulic motor-generator unit

When the complete machine controller judges p_e≤p_L≤p_rAnd SOC of the storage battery is less than S_maxAt this time, since the recoverable energy is large, the solenoid DT3 of the third solenoid directional valve 63, the solenoid DT4 of the first solenoid directional valve 61, and the solenoid DT5 of the second solenoid directional valve 62 are all controlled to be energized, so that the high-pressure oil in the rodless chamber of the master cylinder enters the first motor 31 through the port a of the second solenoid directional valve 65 and enters the second motor 41 through the ports a of the first solenoid directional valve 61 and the second solenoid directional valve 62, respectively, and gravity is jointly performedPotential energy is recovered, and the complete machine controller 21 obtains target rotating speeds of the first generator 32 and the second generator 42 according to the handle signal of the electric control handle 100 so as to obtain the gravitational potential energy recovered by the first generator 32 and the second generator 42.

Wherein the target speed of the first generator 32 is n₁＝[k₁(Y_p-Y₁)+n₀₁]s, recovered power P₂＝T₁×2πn₁＝p₂V₁[k₁(Y_p-Y₁)+n₀₁]s; the target speed of the second generator is n₂＝[k₂(Y_p-Y₁)+n₀₂]s, recovered power P₃＝T₂×2πn₂＝p₃V₂[k₂(Y_p-Y₁)+n₀₂]s; the gravitational potential energy recovered by the first generator and the second generator satisfies P₂×t₂+P₃×t₃＝E_L。

Along with the reduction of the load, the SOC of the storage battery is gradually increased, and when the complete machine controller judges that the SOC of the storage battery is more than or equal to S_maxWhen the energy accumulator 12 recovers the gravitational potential energy, the electromagnet DT3 of the third electromagnetic directional valve 63 is controlled to lose power, the electromagnet DT4 of the first electromagnetic directional valve 61 and the electromagnet DT5 of the second electromagnetic directional valve 62 lose power, and the recovered gravitational potential energy meets the requirement P₁×t₁+P₂×t₂+P₃×t₃＝E_L. When the complete machine controller judges the inlet pressure p of the energy accumulator₁≥p_1maxAnd when the pressure of the hydraulic cylinder reaches the preset pressure, the energy accumulator 12 is controlled to stop recovering the gravity potential energy, the electromagnet DT6 of the fourth electromagnetic directional valve 66 is electrified, and the high-pressure oil of the rodless cavity of the main hydraulic cylinder flows into the oil tank through the T2 port of the proportional directional valve 60 and the A port of the fourth electromagnetic directional valve 66 in sequence.

Note that, p is_rAnd the load is the maximum value of the load interval of the fourth gear.

E. Simultaneous energy recovery of fifth gear accumulator and two hydraulic motor-generator units

When the complete machine controller judges p_r≤p_L≤p_LmaxAnd SOC of the storage battery is less than S_maxAt this time, the recoverable energy reaches the maximum value, and at this time, the principle of firstly hydraulic and then electric energy recovery is followed, so that the whole machine controller controls the electromagnet DT3 of the third electromagnetic directional valve 63 to lose power, so that the high-pressure oil in the rodless cavity in the main hydraulic cylinder sequentially enters the energy accumulator 12 through the T2 port of the proportional directional valve 60 and the P port of the first hydraulic directional valve 64, so that the energy accumulator 12 recovers the gravitational potential energy of the load, and the recovered gravitational potential energy is P₁×t₁＝E_L(ii) a When the complete machine controller judges p₁≥p_1maxAnd meanwhile, controlling the electromagnet DT3 of the third electromagnetic directional valve 63, the electromagnet DT4 of the first electromagnetic directional valve 61 and the electromagnet DT5 of the second electromagnetic directional valve 62 to be electrified so as to enable the two hydraulic motor-generator units to jointly recover the gravitational potential energy to obtain the recovered gravitational potential energy.

The target speed of the first generator is n₁＝[k₁(Y_p-Y₁)+n₀₁]s, recovered power P₂＝T₁×2πn₁＝p₂V₁[k₁(Y_p-Y₁)+n₀₁]s; the target speed of the second generator is n₂＝[k₂(Y_p-Y₁)+n₀₂]s, recovered power P₃＝T₂×2πn₂＝p₃V₂[k₂(Y_p-Y₁)+n₀₂]s; the recovered gravitational potential energy satisfies P₁×t₁+P₂×t₂+P₃×t₃＝E_LWherein t is₂＝t₃。

When the complete machine controller judges that the SOC of the storage battery is more than or equal to S_maxWhen the energy recovery is stopped, the electromagnet DT3 of the third electromagnetic directional valve 63, the electromagnet DT4 of the first electromagnetic directional valve 61 and the electromagnet DT5 of the second electromagnetic directional valve 62 are all de-energized, the electromagnet DT6 of the fourth electromagnetic directional valve 66 is energized at the moment, and the rodless cavity high-pressure oil of the master hydraulic cylinder flows into the oil tank through the T2 port of the proportional directional valve 60 and the A port of the fourth electromagnetic directional valve 66 in sequence.

It should be noted that pr is the maximum load value of the fifth gear load interval.

In this embodiment, the load pressure satisfies: p is a radical of_min<p_d<p_e<p_f<p_Lmax。

An energy recovery system based on a multi-hydraulic motor-energy accumulator electric forklift adopts an energy accumulator 12, a first hydraulic motor-generator unit and a second hydraulic motor-generator unit to form the energy recovery system of the electric forklift, and a pressure signal p acquired by a first pressure sensor_LThe load size is judged, a proper energy recovery unit is selected through the reasonable energy management method, the rated rotating speed of the generator is determined according to the handle signal of the electric control handle 100, the load descending speed is converted into volume speed regulation, better load descending speed control can be obtained while energy recovery is achieved, the load adaptation range of the electric forklift can be expanded, and the energy recovery requirements of different load changes from no-load to full-load can be met.

The utility model discloses in, complete machine controller 21 acquires battery 13's information through the battery management system on battery 13, like the SOC data of battery, this battery management system is current well-known system, and the event is no longer repeated.

The above description is only a preferred embodiment of the present invention, and all equivalent changes and modifications made within the scope of the claims of the present invention should belong to the scope of the claims of the present invention.

Claims (8)

1. The utility model provides an energy recuperation system based on many hydraulic motor-accumulator combination electric fork truck which characterized in that: the master hydraulic cylinder, the energy accumulator, the storage battery and the two hydraulic motor-generator units are respectively connected into a master hydraulic circuit of an electric forklift, a plurality of reversing valves are respectively installed on the master hydraulic circuit, and the master hydraulic cylinder controls the on-off between the master hydraulic cylinder and the energy accumulator and between the master hydraulic cylinder and the two hydraulic motor-generator units through the on-off of each reversing valve;

the control unit comprises a complete machine controller which is used for calculating a target rotating speed according to a handle signal transmitted by the electric control handle and judging the current load interval of the electric forklift through the pressure of a rodless cavity on the main hydraulic cylinder so as to control the on-off of each reversing valve according to the load interval in the load descending process; the control unit also comprises a motor controller which controls the rotating speed of the generator in the hydraulic motor/generator unit according to the target rotating speed output by the complete machine controller.

2. The energy recovery system based on a multi-hydraulic motor-accumulator combination electric forklift according to claim 1, characterized in that: the two hydraulic motor-generator units are respectively provided with the motor controller, and correspond to a first hydraulic motor-generator unit and a second hydraulic motor-generator unit respectively;

the first hydraulic motor-generator unit comprises a first motor and a first generator, an output shaft of the first motor is in transmission connection with a rotating shaft of the first generator, the motor controller paired with the first motor is a first motor controller, and the first motor controller is coaxially connected with the first generator; the second hydraulic motor-generator unit comprises a second motor and a second generator, an output shaft of the second motor is in transmission connection with a rotating shaft of the second generator, the motor controller paired with the second motor is a second motor controller, and the second motor controller is coaxially connected with the second generator;

the signal output end of the complete machine controller is respectively and electrically connected with the signal input ends of the first motor controller and the second motor controller, the power supply ends of the first motor controller and the second motor controller are both connected with the power supply end of the storage battery, and the signal output end of the electric control handle is electrically connected with the signal input end of the complete machine controller.

3. The energy recovery system based on a multi-hydraulic motor-accumulator combination electric forklift according to claim 2, characterized in that: the reversing valves are respectively and correspondingly a three-position six-way proportional reversing valve, a two-position two-way first electromagnetic reversing valve, a two-position two-way second electromagnetic reversing valve and a two-position two-way fourth electromagnetic reversing valve, a two-position three-way third electromagnetic reversing valve and a two-position two-way first hydraulic control reversing valve and a two-position two-way second hydraulic control reversing valve.

4. The energy recovery system based on multi-hydraulic motor-accumulator combination electric fork-lift truck of claim 3, characterized in that: the rod cavity of the master hydraulic cylinder is connected with an oil tank, the rodless cavity of the master hydraulic cylinder is connected with the port A of the proportional reversing valve, the port C of the proportional reversing valve is connected with the oil tank, the port T2 of the proportional reversing valve is respectively connected with the port P of the first hydraulic control reversing valve, the port P of the second hydraulic control reversing valve and the port P of the fourth electromagnetic reversing valve, the port A of the fourth electromagnetic reversing valve is connected with the oil tank, the port A of the first hydraulic control reversing valve is connected with the hydraulic control energy accumulator, the port A of the second hydraulic control reversing valve is connected with the oil tank through a third one-way valve, a branch is arranged at a collection node between the port A of the second hydraulic control reversing valve and the oil outlet of the third one-way valve and is respectively connected with the ports P of the first electromagnetic reversing valve and the second electromagnetic reversing valve, and the right port D1 of the first hydraulic control reversing valve and the right port D2 of the second hydraulic control reversing valve are respectively connected with the port A of the third electromagnetic reversing valve, the T port of the third electromagnetic reversing valve, the left hydraulic control port of the first hydraulic control reversing valve and the left hydraulic control port of the second hydraulic control reversing valve are connected with an oil tank; the port A of the first electromagnetic directional valve is connected with the oil inlet of the first motor, the port A of the second electromagnetic directional valve is connected with the oil inlet of the second motor, and the oil outlets of the first motor and the second motor are both connected with an oil tank.

5. The energy recovery system based on multi-hydraulic motor-accumulator combination electric fork-lift truck of claim 4, characterized in that: the hydraulic pump system further comprises a driving unit, wherein the driving unit comprises a motor, a main hydraulic pump and a pilot hydraulic pump, the pilot hydraulic pump is coaxially connected with the motor, and the pilot hydraulic pump is coaxially connected with the main hydraulic pump; and the oil inlets of the main hydraulic pump and the pilot hydraulic pump are both connected with an oil tank, the oil outlet of the main hydraulic pump is connected with the oil inlet of a first one-way valve, the oil outlet of the first one-way valve is divided into two paths, one path is connected with a T1 port of the proportional reversing valve, the other path is connected with a P port of the proportional reversing valve through a second one-way valve, and the oil outlet of the pilot hydraulic pump is connected with a P port of a third electromagnetic reversing valve through a fourth one-way valve.

6. The energy recovery system based on a multi-hydraulic motor-accumulator combination electric fork-lift truck according to any of claims 2-5, characterized in that: the control unit further comprises a plurality of pressure sensors, each pressure sensor corresponds to a first pressure sensor, a second pressure sensor, a third pressure sensor and a fourth pressure sensor, the first pressure sensor is installed at the position of the rodless cavity of the master cylinder, the second pressure sensor is installed at the position of an inlet and an outlet of the energy accumulator, the third pressure sensor is installed at the position of an oil inlet of the first motor, and the fourth pressure sensor is installed at the position of an oil inlet of the second motor;

the signal output ends of the first pressure sensor, the second pressure sensor, the third pressure sensor and the fourth pressure sensor are respectively and electrically connected with the signal input end of the complete machine controller.

7. The energy recovery system based on multi-hydraulic motor-accumulator combination electric fork-lift truck of claim 6, characterized in that: the load interval is preset in the complete machine controller and is divided into a first gear, a second gear, a third gear, a fourth gear and a fifth gear; the first gear corresponds to energy recovery of an energy accumulator, the second gear corresponds to energy recovery of a first hydraulic motor-generator unit, the third gear corresponds to energy recovery of a second hydraulic motor-generator unit, the fourth gear corresponds to joint energy recovery of two hydraulic motor-generator units, and the fifth gear corresponds to joint energy recovery of the energy accumulator and the two hydraulic motor-generator units.

8. The energy recovery system based on a multi-hydraulic motor-accumulator combination electric forklift according to claim 7, characterized in that: the first gear is p_L≤p_min，p_LData collected for the first pressure sensor, p_minA minimum load pressure for the hydraulic motor-generator unit that produces no additional losses;

the second gear is p_min≤p_L≤p_dAnd SOC of the storage battery is less than S_max，p_dIs the maximum load value of the second gear load interval, S_maxThe maximum allowable electric quantity value of the storage battery;

the third gear is p_d≤p_L≤p_eAnd SOC of the storage battery is less than S_max，p_eThe load is the maximum value of the load interval of the third gear;

the fourth gear is p_e≤p_L≤p_rAnd SOC of the storage battery is less than S_maxPr is the maximum load value of the fourth gear load interval;

the fifth gear is p_r≤p_L≤p_LmaxAnd SOC of the storage battery is less than S_maxAnd pr is the maximum load value of the fifth gear load interval.

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