DE202015105609U1 - Pressure control module of a coolant recovery device - Google Patents

Abstract

A pressure control module of a refrigerant recovery device, comprising: a gas path flow divider module having a high pressure connection port, a low pressure communication port, and two pairs of output ports and input ports, the high pressure communication port connected to the output ports, wherein the low pressure communication Terminal is connected to the input terminals to provide a function of a gas path flow distribution for collecting refrigerant from a recovery machine by the refrigerant recovery device to a storage tank, wherein the high-pressure refrigerant connection port and the low-pressure refrigerant connection port each with an electromagnetic High pressure valve, a low pressure electromagnetic valve, a high pressure sensor and a low pressure sensor are provided to a coolant connection control and a pressure determination de s high-pressure connection port and the low-pressure connection port for a coolant recovery, wherein the two output ports of the gas path flow divider module are each connected to two input ports of two heat exchangers arranged in the coolant recovery device; two pressure variable cylinders each having an input port and an output port, the output ports respectively connected to the two input ports of the gas path flow divider module, the input ports of the pressure variable cylinder respectively connected to the output ports of the two heat exchangers to which the gas path flow divider module is connected To obtain coolant from the heat exchangers, wherein the pressure variable cylinder each having a piston / connecting rod assembly, wherein the piston / connecting rod assembly has an end which is received from an inner cylindrical surface of the pressure variable cylinder, so that the Hin and fro movement of the piston / connecting rod assembly varies with the refrigerant pressure in the pressure variable cylinder, which is then passed through the output port of the pressure variable cylinder to the input port of the gas path flow divider module w ird; a motor having a rotating shaft coupled to an end of the piston / connecting rod assembly of each of the pressure variable cylinders to drive the piston / connecting rod assembly to linearly reciprocate the pressure variable Perform cylinder; and at least one control circuit electrically connected to the high-pressure-side electromagnetic valve, low-pressure-side electromagnetic valve, high-pressure-side pressure sensor and low-pressure-side pressure sensor of the gas path flow division module, to open and close the high-pressure-side electromagnetic valve, the low-pressure-side electromagnetic valve coupled to the gas path flow division module and to control the activation and deactivation of the engine according to the pressure values detected by the high-pressure side pressure sensor and the low-pressure side pressure sensor.

Description

Background of the invention

1. Field of the invention

The present invention relates to a pressure operation control module of a refrigerant recovery device, and more particularly to one utilizing a pair of high-pressure side and low-pressure side electromagnetic valves and a control circuit for controlling the operation of high and low pressure of a refrigerant recovery device and the operation of an engine.

2. State of the art

Coolant recovery devices are widely used in applications for recovering and collecting used coolant from coolant driven machines, such as air conditioners and refrigerators. A conventional refrigerant recovery device generally includes a high-pressure connection port and a low-pressure communication port that are selectively connected to a refrigerant recovery machine and a storage tank for recovering the used coolant from the refrigerant recovery machine and storing it in the storage tank. The conventional refrigerant recovery device is provided with a single pressure switch to control activation and deactivation of a motor-based power source disposed within the refrigerant recovery device. Such a pressure switch is unable to identify the pressure level of the high pressure connection port or the low pressure connection port and is actuated by a setting based on the coolant pressure in controlling the activation and deactivation of the motor based power source of the coolant recovery device is done. This prevents the timings for activating and deactivating the refrigerant recovery device from meeting the requirement of high-precision operation. Further, the high-pressure connection port and the low-pressure connection port of the conventional refrigerant recovery device must be manually operated to rotate the switching valves to open and close the high-pressure connection port and the low-pressure connection port of the refrigerant recovery device. This also leads to inconvenience of operation for an operator. Further, the opening and closing of the opening switches are manually operated by an operator who visually monitors a pressure gauge reading of the high-pressure connection port and the low-pressure connection port of the coolant recovery device, and also relies on the experience thereof to control the opening and closing the high-pressure connection port and the low-pressure connection port of the refrigerant recovery device, which makes it difficult to control the sequence and timing of opening or closing in an accurate and easy manner, resulting in a low efficiency of the refrigerant recovery. Further, the remaining coolant may be accumulated in pipes and leakage of coolant may be present. These are problems with conventional coolant recovery equipment that needs to be addressed.

Further, a conventional coolant recovery device may include a pressure variable cylinder in which a motor drives a piston / link rod assembly to reciprocate into the pressure variable cylinder. However, such movement can not be maintained in a state of movement in a linear fashion along a central axis and would result in wear between a piston head and the piston / connecting rod assembly and an inner surface of the pressure variable cylinder, eventually does not make it possible to maintain airtightness between the pressure variable cylinder and the piston / connecting rod assembly and thus results in leakage. To remedy this problem, the output power of the motor must be increased to compensate for the loss caused by this leakage, resulting in an increase in the power consumption of the entire device. This is generally not economical. Further, the rated power of the drive motor C must be increased, and this leads to an increase in the equipment cost of the refrigerant recovery device, which does not make it economical.

Prior art documents are known in the art. For example, this discloses Taiwanese utility model M380467 an electrical measuring device for a refrigerant recovery machine, wherein an electronic measuring device and a pressure sensor are used to control the activation and deactivation of the refrigerant recovery machine. Although the problem of non-precise times of activation and deactivation of the above-described refrigerant recovery device can be solved with a single pressure switch, the high-pressure connection port and the low-pressure communication port (namely, the input port 111 and the output power 112 ) of the refrigerant recovery machine of this prior art document is structured in such a manner that a manual operation for turning a switch ( 14 ) (as in 1 of the prior art document) is required to control the opening or closing of the high-pressure connection port and the low-pressure communication port. There is still the same problem that it is difficult to control the sequence and timing for opening or closing the high-pressure connection port and the low-pressure connection port of the conventional refrigerant recovery machine, resulting in low operating efficiency of the refrigerant recovery machine and leads to problems of residual coolant and leakage of coolant that has accumulated in the pipes.

In addition, the US 2011/0120242 a portable refrigerant recovery device and the US 7,887,881 discloses a portable refrigerant recovery device. Both disclose the typical refrigerant recovery device, such as those conventional ones discussed above, which also suffer from the same drawbacks and problems of inaccurate operation of activating and deactivating the refrigerant recovery devices, which are controlled by use of a single pressure switch and also the disadvantages and disadvantages Have problems that it is difficult to accurately control the sequence and times of opening or closing of a high-pressure connection port and a low-pressure connection port of the refrigerant recovery device, and consequently lower operating efficiency of the refrigerant recovery device and residual refrigerant and leakage of refrigerant have accumulated in pipes.

Outline of the invention

The known refrigerant recovery device in and those of the prior art use a motor controllable for activation and deactivation by a single pressure switch, which detects pressures and stops the operation of the motor of the refrigerant recovery device, so that the times of opening or closing of the refrigerant recovery device not meet the requirements for a precise operation and the coolant recovery device having a high-pressure connection port and a low-pressure connection port, which are structured so that the opening or closing of the high-pressure connection port and the low-pressure connection port of Coolant recovery device can be performed only by a manual operation of rotary switch valves by an operator who visually observes the pressure gauge displays, and the associated experience g, which makes it difficult to control the control sequence and the times of opening and closing, and easily causes the problems and disadvantages that the recovery efficiency of the coolant is low, and remaining coolant and leakage in the pipes accumulated coolant leads. Further, the coolant recovery means comprises a pressure variable cylinder in which a piston / connecting rod assembly is moved, but such movement can not be maintained linearly along a central axis, resulting in wear of the piston / connecting rod assembly and eventually leakage that occurs in the pressure variable cylinder, which in turn leads to the requirement of increasing the engine power of the refrigerant recovery means and to an increase in power consumption.

The present invention provides a pressure operation control module for a refrigerant recovery device, comprising:
a gas path flow splitting module having a high pressure connection port, a low pressure communication port and two pairs of output ports and input ports, the high pressure communication port connected to the output ports, the low pressure communication port connected to the input ports to provide a function of gas path flow partitioning for collecting refrigerant from a recovery machine by the refrigerant recovery device to a storage tank, the refrigerant high pressure connection port and the low pressure refrigerant connection port each having a high pressure electromagnetic valve, a low pressure electromagnetic valve, a high-pressure sensor and a low-pressure sensor are provided to perform a refrigerant connection control and a pressure detection of the high-pressure connection port and the low-pressure connection port for a K to provide coolant recovery, wherein the two output ports of the gas path flow divider module are each connected to two input ports of two heat exchangers arranged in the coolant recovery device;
two pressure variable cylinders each having an input port and an output port, the output ports respectively connected to the two input ports of the gas path flow divider module, the input ports of the pressure variable cylinder respectively connected to the output ports of the two heat exchangers to which the gas path flow divider module is connected To get coolant from the heat exchangers, wherein the pressure variable cylinders each comprise a piston / link rod assembly, the piston / link rod assembly having an end received by an inner cylindrical surface of the pressure variable cylinder such that reciprocation of the pistons / Connecting rod arrangement varies with the refrigerant pressure in the pressure variable cylinder, which is then passed through the output port of the pressure variable cylinder to the input port of the gas path flow divider module;
a motor having a rotating shaft coupled to one end of the piston / connecting rod assembly of each of the pressure variable cylinders to drive the piston / connecting rod assembly to linearly reciprocate the pressure variable Perform cylinder; and
at least one control circuit electrically connected to the high-pressure side electromagnetic valve, the low-pressure side electromagnetic valve, the high-pressure-side pressure sensor, and the low-pressure-side pressure sensor of the gas path flow division module, to open and close the high-pressure-side electromagnetic valve, the low-pressure-side electromagnetic valve, which are coupled to the gas path flow division module and to control the activation and deactivation of the engine according to the pressure values detected by the high-pressure side pressure sensor and the low-pressure side pressure sensor.

In the pressure operation control module of the refrigerant recovery device, the high-pressure-side electromagnetic valve and the low-pressure-side electromagnetic valve of the gas path flow dividing module are further anti-explosion electromagnetic valves.

In the aforementioned pressure control module of the refrigerant recovery device of the present invention, the piston / connecting rod assembly of each of the pressure variable cylinders includes:
a connecting rod having two ends respectively forming at least a connecting portion and a hinge portion, the connecting portion being connected between a plurality of cams connected in a cascade shape and a bearing, one of the cams being connected to the rotary shaft of the motor is to have a torque to the connecting portion of the connecting rod, the hinge portion having a ball bearing, an elastic washer, a washer and a lockable in a groove locking ring;
a piston head having one end attached to the two sleeves, the sleeves being respectively mounted on two opposite sides of the hinge portion of the connecting rod;
an axis extending through the two sleeves of the piston head and the bearing, the elastic washer, the washer and the lockable in the groove locking ring of the joint connection of the connecting rod; and
two axle mounting rings each attached to two ends of the axle to form a pivotal connection structure between the hinge portion of the connecting rod and the sleeves of the piston head allowing relative rotation therebetween such that when the piston head is disposed in and within the pressure variable cylinder a linear motion is achieved, which maintains a gap-free close arrangement within the surface of the pressure-variable cylinder.

In the pressure recovery control module of the refrigerant recovery device described above, the connection portion and the connecting rod of the piston / connecting rod assembly of the pressure variable cylinders have an opening formed therein. The opening receives a bearing disposed therein to be coupled to a rotary shaft of the motor. In the pressure recovery control module of the refrigerant recovery device described above, the hinge portion of the connecting rod of the piston / connecting rod assembly of each of the pressure variable cylinders includes a slot formed therein for receiving the bearing, the elastic washer, the washer, and the in-groove lock ring therein is appropriate.

In the pressure recovery control module of the refrigerant recovery device described above, the hinge portion of the connecting rod of the piston / connecting rod assembly of each of the pressure variable cylinders includes a circumferential groove formed on one side of the slot on the groove attachable lock ring fitted therein.

In the pressure recovery control module of the refrigerant recovery device described above, the sockets of the piston head and the piston / connecting rod assembly of the pressure variable cylinders are each provided with an opening therein for the extension of the axis.

In the pressure recovery control module of the refrigerant recovery device described above, the axis of the piston / connecting rod assembly of the pressure variable cylinders has two ends that form recessed grooves for receiving the axle mounting rings fitted therein.

In the pressure recovery control module of the refrigerant recovery device described above, the axis fixing rings of the piston / connecting rod assembly of the pressure variable cylinders are C-clips.

In the previously described pressure control module of the refrigerant recovery device, the control circuit comprises:
a microprocessor that outputs functions of reading the high and low refrigerant pressures and temperature, displaying, alarming and outputting the open / close control signals for the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve and the activation / deactivation control signals for the engine ;
two A / D converters respectively and electrically connected to the high pressure side pressure sensor and the low pressure side pressure sensor of the gas path flow division module and the microprocessor to convert the pressure detection signals of the high pressure side pressure sensor and the low pressure side pressure sensor into digital data applied to the microprocessor;
a temperature sensor electrically connected to the microprocessor for determining the temperature of the coolant flowing in the gas path flow splitting module and generating a corresponding temperature signal to the microprocessor;
at least one memory connected to the microprocessor and the pressure data of the various models and types of refrigerant recovery means and data for the opening / closing time of the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve of the gas path flow splitting module and the activation / deactivation control of the motor for therein stores the refrigerant recovery operation supplied to the microprocessor as a reference for opening / closing the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve and activating / activating the motor;
a push-button assembly that is electrically connected to the microprocessor for manual operation, the opening / closing time of the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve of the gas path flow splitting module and the control of activating / deactivating the motor of a refrigerant recovery operation, the display and memory Set operating modes and control instructions for the microprocessor;
a display interface and a display device, wherein the display interface is connected to the microprocessor and the display device so that the microprocessor drives the display interface to cause the display device to open / close the high pressure side electromagnetic valve and the low pressure side electromagnetic valve of the gas path flow splitting module and indicate the control of the activation / deactivation of the engine of the refrigerant recovery operation and the status and information regarding setting, display, control or alerting;
an alarm device connected to the microprocessor for being controlled by the microprocessor to issue an alarm;
a motor controller coupled to the microprocessor and the motor such that the microprocessor controls activation or activation of the motor;
a drive circuit coupled to the microprocessor and the high pressure side electromagnetic valve and the low pressure side electromagnetic valve of the gas path flow dividing module so as to be driven by the microprocessor to control the opening and closing of the high pressure side electromagnetic valve and the low pressure side electromagnetic valve; and
a power supply circuit providing DC power to the microprocessor, the analog to digital converters, the temperature sensor, the memory, the push button assembly, the display interface, the display, the alarm, the motor control, and the driver circuitry.

In the previously described pressure control module of the refrigerant recovery device, the microprocessor is connected to a time circuit for generating an alarm reset signal for the microprocessor to reset the alarm to return the alarm device to a state in which it is not activated.

In the pressure recovery control module of the refrigerant recovery device described above, the microprocessor is connected to a communication interface circuit, and the communication interface circuit is connected to an electronic device.

In the pressure recovery control module of the refrigerant recovery device described above, the communication interface circuit to which the microprocessor is connected includes a universal serial bus (USB) interface circuit.

In the above-described pressure recovery control module of the refrigerant recovery device, the microprocessor is connected to a wireless communication circuit for communicating pressure data for refrigerant recovery and data and status of the opening in a wireless manner. Close time of the high-pressure side electromagnetic valves and the low-pressure side electric valves and the control of the activation / deactivation of the engine of the refrigerant recovery operation of the refrigerant recovery operation to receive or send.

In the previously described pressure control module of the refrigerant recovery device, the wireless data transmission circuit to which the microprocessor is connected comprises a Bluetooth transmission circuit.

In the previously described pressure control module of the refrigerant recovery device, the wireless communication circuit to which the microprocessor is connected includes a wireless USB transmission circuit.

In the above-described pressure operation control module of the refrigerant recovery device, the display device comprises a liquid crystal display device.

In the previously described pressure control module of the refrigerant recovery device, the alarm device comprises an audio / video alarm device.

The efficiency of the pressure control module of the refrigerant recovery device according to the present invention is that the connecting portion and the hinge portion of the connecting rod of the piston / connecting rod assembly of the pressure variable cylinder are structured to provide a linear movement of the piston / connecting rod assembly in the inner Provide the cylinder surface of the pressure variable cylinder along a central axis in a manner in which it is kept in tight engagement to ensure that the internal pressure of the pressure variable cylinder is prevented from forming a leak and the piston head of the piston / connecting rod - Arrangement does not wear. Further, the control circuit controls the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve to open and close the high-pressure and low-pressure connection ports of the gas path flow dividing module, respectively, and controls the activation and deactivation of the engine of the refrigerant recovery device so as to be accurate and accurate efficient manner of achieving the opening and closing of the high pressure and low pressure connection ports of the refrigerant recovery device, and the operation of the engine, allowing complete control of the times of opening / closing of the high pressure and low pressure connection ports of the refrigerant recovery device , and allows operation of the engine without the need for using a single pressure switch and manual rotation for shifting. Further, wired or wireless techniques may be used to efficiently send the operating information of the refrigerant recovery device to a remote control center or electronic device of a monitoring operator for monitoring and recording, and may also enable data sharing and storage among multiple refrigerant recovery devices with the control circuit without requiring an operator to retype the data and establish the data. Also, the data may be timely updated by wired or wireless transmission to improve the operation of the refrigerant recovery device of the present invention and enhance the possibilities for data exchange therefrom.

Brief description of the drawings

The present invention will become apparent to those skilled in the art upon reading the following description of preferred embodiments thereof with reference to the accompanying drawings, in which:

1 Fig. 12 is a perspective view showing a pressure operation control module of a refrigerant recovery device according to the present invention;

2 Fig. 12 is a perspective view showing the connection between the pressure operation control module of the refrigerant recovery device according to the present invention and the pressure variable cylinders, the heat exchangers and a motor of the refrigerant recovery device;

3 Fig. 12 is a perspective view illustrating a piston / connecting rod assembly of the pressure variable cylinder of the pressure control module of the refrigerant recovery device according to the present invention;

4 Figure 11 is an exploded view of the piston / connecting rod assembly of the pressure variable cylinder of the pressure control module of the refrigerant recovery device according to the present invention;

5 Fig. 12 is a perspective view illustrating the connection between the piston / connecting rod assembly of the pressure variable cylinder of the pressure control module and the refrigerant recovery device according to the present invention and a motor;

6 Fig. 10 is a side elevational view showing a state of a piston head of the piston / connecting rod assembly of the pressure control module of the coolant recovery device according to the present invention when a rotation angle of a cam is in the 0 ° position.

7 Fig. 10 is a side elevational view showing a state of the piston head of the piston / connecting rod assembly of the pressure operation control module of the refrigerant recovery device according to the present invention when the rotational angle of the cam is in a 90 degree angular position.

8th Fig. 10 is a block diagram of a control circuit of the pressure operation control module of the refrigerant recovery device according to the present invention;

9 another embodiment of the control circuit of the pressure control module of the refrigerant recovery device according to the present invention;

10 Fig. 12 is a perspective view showing an example of the pressure operation control module of the refrigerant recovery device according to the present invention; and

11 FIG. 3 is a schematic diagram illustrating an operation of the refrigerant recovery device of FIG 10 to recover coolant.

Detailed Description of the Preferred Embodiments

With reference to 1 and 2 The present invention provides a print operation control module 100 a coolant recovery device ready. The pressure control module includes a gas path flow divider module 10 that has a high pressure connection port 11 , a low pressure connection port 12 and two pairs of one output terminal 13 and an input terminal 14 having. The high pressure connection port 11 is with the output connections 13 connected. The low pressure connection port 12 is with the input terminals 14 connected. The high pressure connection port 11 and the low pressure connection port 12 of the gas path flow splitting module 10 are corresponding to a high pressure side electromagnetic valve 111 , a high pressure side pressure sensor 112 and a low-pressure side electromagnetic valve 121 , a low pressure side pressure sensor 122 connected to each opening and closing the high pressure connection port 11 and the low pressure connection port 12 to taxes and the coolant pressures at the high pressure connection port 11 and at the low pressure connection port 12 to investigate. The high pressure side electromagnetic valve 111 and the low-pressure side electromagnetic valve 112 are not limited to any specific shape and an anti-explosion electromagnetic valve is used as an example in the present invention. The output connections 13 of the gas path flow splitting module 10 are with the input terminals 310a the two heat exchangers 310 connected in a coolant recovery device 300 (as in 2 is shown) arranged.

At least two pressure-variable cylinders 20 each comprise an output terminal 21 and an input terminal 22 , The output connections 21 are corresponding to the two input terminals 14 of the gas path flow splitting module 10 connected. The input terminals 22 are corresponding to the output terminals 310b the two heat exchangers 310 in the coolant recovery device 300 (as in 10 ), so that the gas path flow splitting module 10 a function of gas path flow partitioning for collecting coolant from a recovery machine 200 (as in 10 shown) by the coolant recovery device 300 to a storage tank 400 provides.

With reference to 3 and 4 include the pressure variable cylinders 20 each an inner cylinder surface formed therein 23 , The pressure variable cylinders 20 each comprise a piston / connection rod arrangement 24 , The piston / connecting rod assembly 24 includes a connecting rod 241 , a piston head 25 , an axis 26 and two axle mounting ring 27 . 28 , The connection rod 241 has two ends corresponding to at least one connection area 2411 and a joint area 2412 form. The connection area 2411 includes an opening formed therein 2411a , The opening 2411a takes a warehouse located in it 2411b on. The joint area 2412 includes a warehouse 2412a , an elastic washer 2412b , a washer 2412c and an attachable in a groove locking ring 2412d , The connection area 2412 includes a slot formed therein 2412E and a circumferential groove 2412f on one side of the slot 2412E is trained. The slot 2412E take the camp 2412a , the elastic washer 2412b , the washer 2412c and the attachable in the groove locking ring 2412d so that they can be sequentially inserted therein with the lock ring attachable in the groove 2412d are mounted in the circumferential groove 2412f is fitted so as the bearing 2412a , the elastic washer 2412b and the washer 2412c in the slot 2412E to fix.

The piston head 25 has an end where two sleeves (eyes) 251 are attached. The thimbles 251 are those with an opening formed therein 2511 Mistake. The thimbles 251 are each on two opposite sides of the joint area 2412 the connecting rod 241 arranged. The piston head 25 is in the internal cylinder surface 23 included in each of the pressure variable cylinders 20 is formed.

The axis 26 has two ends, each with a recessed groove 261 . 262 have formed therein. The axis 26 extends through the openings 2511 the two muffs 251 of the piston head 25 and the camp 2412a , the elastic washer 2412b , the washer 2412c and the attachable in the groove locking ring 2412d of the joint area 2412 the connecting rod 241 and is absorbed by it. The two axle mounting rings 27 . 28 are correspondingly in the gutted grooves 261 . 262 the two ends of the axle 26 fitted and secured therein to a pivotal connection structure between the hinge region 2412 the connecting rod 241 and the thimbles 251 and the piston head 25 to form, which allows a relative rotation in between.

It will open 5 . 6 and 7 Referenced. An engine 30 includes a rotary shaft 31 , The rotary shaft 31 is with at least one cam 40 and a warehouse 50 connected. The cam 40 is also in a cascade shape with a plurality of cams 41 . 42 . 43 and a warehouse 51 with connection areas 2411 the connecting rod 241 of the two piston / link rod assemblies 24 connected, which are arranged in between. In other words, the connection areas 2411 the connecting rods 241 of the two piston / link rod assemblies 24 are corresponding between the two cams 41 . 42 and the cams 42 . 43 coupled. The side surface of the cam 43 that does not match the connection area 2411 the piston / connecting rod assembly 24 is connected to the warehouse 51 connected. The motor 30 provides torque through the rotary shaft 31 to the cam 40 , so that the torque through the cams 41 . 42 and 43 is applied to the connection areas 2411 the connecting rods 241 the piston / connecting rod assembly 24 to drive them to move, causing the piston body 25 the piston / connecting rod assembly 24 rotatable by means of the sleeves 251 at the joint areas 2412 connected by the piston head 25 be driven to get inside the inner cylinder surface 23 of the pressure variable cylinder, each of which is a straight linear axis. The 6 and 7 set the relative position of the piston head 25 the piston / connecting rod assembly 24 in the inner cylinder surface 23 of the pressure variable cylinder 20 each for the cams 40 at a rotational angle of 0 ° and 90 °, respectively, wherein it is clearly shown that the piston head 25 the piston / connecting rod assembly 24 constant on a linear axis in the inner cylinder surface 23 of the pressure variable cylinder 20 can be held for a reciprocating motion to ensure that the piston head 25 the piston / connecting rod arrangement 24 and the inner cylinder surface 23 of the pressure variable cylinder 20 held in an airtight state with a close cooperation without any leakage in between.

It will open 8th Referenced. A control circuit 60 is electrically connected to the high pressure side electromagnetic valve 111 , the high pressure side pressure sensor 112 , the low pressure side electromagnetic valve 112 and the low-pressure side pressure sensor 122 of the gas path flow splitting module 10 connected to the opening and closing of the high-pressure side electromagnetic valve 111 , the low-pressure side electromagnetic valve 122 to control with the gas path flow splitting module 10 coupled, and the activation and deactivation of the engine 30 according to the pressure values provided by the high-pressure side pressure sensor 112 and the low-pressure side pressure sensor 122 be determined to control.

The control circuit 60 is not limited to any specific form, and an example given in the present invention includes a microprocessor 61 , two analog / digital converters 62 . 63 , a temperature sensor 64 , at least one memory 65 , a push-button arrangement 66 , a display interface 67 , a display device 68 , an alarm device 61 , a motor control device 70 , a drive circuit 71 and a power supply circuit 72 , where the microprocessor 61 Functions for reading the high and low coolant pressures and temperatures, for displaying, alarming and outputting the opening / closing control signals for the high pressure solenoid valve 111 and the low-pressure side electromagnetic valve 112 and activation / deactivation control signals for the engine 30 provides. The analog / digital converter 62 . 63 are corresponding to the high pressure side pressure sensor 112 and the low-pressure side pressure sensor 50 and the microprocessor 61 connected to the detection signals 62a . 63a the high pressure side pressure sensor 112 and the low-pressure side pressure sensor 122 into digital data 62b . 63 to convert that to the microprocessor 61 be created. The temperature sensor 64 is electric with the microprocessor 61 connected to to determine the temperature of the coolant in the gas path flow splitting module 10 flows and a corresponding temperature signal 64a to the microprocessor 61 to create. The memory 65 is with the microprocessor 61 connected therein and stores pressure data of various models and types of refrigerant recovery device 300 and data for the opening / closing timing of the high-pressure side electromagnetic valves and the low-pressure side electromagnetic valves 121 and the activation / deactivation control of the engine 30 for refrigerant recovery operations sent to the microprocessor 61 as a reference for opening / closing the high-pressure side electromagnetic valve 111 and the low-pressure side electromagnetic valve 121 and activation / activation of the engine 30 to be delivered.

The pushbutton arrangement 66 is electric with the microprocessor 61 for manual operation to the opening / closing timing of the high-pressure side electromagnetic valve 111 and the low-pressure side electromagnetic valve 121 and the control of activation / activation of the engine 30 a refrigerant recovery operation, the display and storage operations and the control instructions to the microprocessor 61 adjust. The display interface 67 the display device 68 are arranged so that the display interface 67 with the microprocessor 61 and the display device 68 connected, so the microprocessor 61 the display interface 67 can control so that the display device 68 the opening / closing timing of the high-pressure side electromagnetic valve 111 and the low-pressure side electromagnetic valve 121 and the control of the activation / deactivation of the engine 30 of a refrigerant recovery operation as and the status and information regarding setting, display, storage, control or alerting. The display device 68 is not limited to a specific shape, and a liquid crystal display device is used as an example in the present invention. The alarm device 69 is with the microprocessor 61 connected and is through the microprocessor 61 controlled to give an alarm. The alarm device 69 is not limited to a specific form and an audio / video alarm device is used as an example in the present invention. The engine control device 70 is with the microprocessor 61 and the engine 30 connected, so the microprocessor 61 Activation or activation of the engine 30 controls. The drive circuit 61 is with the microprocessor 61 , the high-pressure side electromagnetic valve 111 and the low-pressure side electromagnetic valve 112 coupled to the microprocessor 61 to be controlled to open and close the high-pressure side electromagnetic valves 111 and the low-pressure side electromagnetic valves 121 to control. The power supply circuit 72 supplies a direct current to the microprocessor 61 , the analog / digital converter 62 . 63 , the temperature sensor 64 , the memory 65 , the push buttons arrangement 66 , the display interface 67 , the display device 68 , the alarm device 69 , the engine control device 70 and the driver circuit 71 ,

It will open 9 Referenced. It will be another embodiment of the control circuit 60 of the print operation control module 100 for a refrigerant recovery device according to the present invention, wherein the microprocessor is provided with at least one reset circuit 73 , a communication interface circuit 74 and a wireless communication circuit 75 is coupled. The reset circuit 73 may be an alarm reset signal 72a to the microprocessor 61 to reset an alarm to cause the alarm device 69 returns to a state where it is not activated. The communication interface circuit 74 is not limited to a specific form, and a universal serial bus (USB) interface circuit is used as an example in the present invention. The communication interface circuit 74 is in a wired manner to an electronic device 500 connected to in a wired manner pressure data for the refrigerant recovery and data and status of the opening / closing timings of the high-pressure side electromagnetic valves 111 and the low-pressure side electromagnetic valves 122 and the control of the activation / deactivation of the engine 30 in the refrigerant recovery process to transmit and receive. The electronic device 500 is not limited to a specific form and an electronic device that provides data communication, for example, as a computer, a portable computer, a smart phone used as an example of the present invention.

The wireless communication circuit 75 is not limited to a specific form, and a Bluetooth transmission circuit and a USB wireless transmission circuit are exemplified in the present invention in a wireless manner, pressure data of the refrigerant recovery and data and status of the opening / closing timings of the high-pressure side electromagnetic valves 111 and the low-pressure side electromagnetic valves 121 and the control of the activation / deactivation of the engine 30 receive and send the coolant recovery process.

It will open 10 and 11 Referenced. An example of the print operation control module 100 for a refrigerant recovery device is provided, wherein a control device 100 in the coolant recovery device 300 (as in 10 is shown), wherein the high-pressure connection port 11 and the low pressure connection port 12 of the gas path flow splitting module 10 each via pipes 340 . 350 to a fluid port 410 the storage tank and a gas connection 210 the recovery machine 200 are connected. A fluid connection 420 the storage tank 400 is over a pipe 260 with a fluid connection 220 the recovery machine 200 (as in 11 shown) connected. The recovery machine 200 and the storage tank 400 are not limited to any specific shape, and an air conditioner or a gas cylinder are used as examples in the present invention. By pressing and pressing the pushbutton assembly 66 the control circuit 60 and the display by the display device 68 is provided, the model and the type of recovery machine 200 from which to recover refrigerant, selected to the control circuit 60 to enable the opening timing and the closing timing of the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve 122 and the activation and deactivation of the engine 30 the coolant recovery device 300 to control. In other words, the automatic operations of the high pressure side electromagnetic valve 111 and the low-pressure side electromagnetic valve 122 and the engine are run until the coolant is completely removed from the recovery machine 200 is recovered and in the storage tank 400 is stored when the control circuit 60 automatically the high pressure solenoid valve 111 and the low-pressure side electromagnetic valve 122 flows and the engine 30 thereby preventing any residual refrigerant and avoiding leakage of refrigerant in the tubes 340,3,150,360 to ensure that the refrigerant recovery operation of the refrigerant recovery device 300 is done in a more accurate way. After the coolant recovery device 300 the recovery of the coolant of the recovery machine 200 and the storage tank 400 has completed, the alarm can 69 the control circuit 60 , in the 3 and 4 shown, an audio / video alarm issued to notify an operator and the operator can then push the button assembly 66 press to alarm the alarm 69 reset.

Furthermore, the print operation control module 100 for a refrigerant recovery device according to the present invention, the communication interface circuit 64 and the wireless communication circuit 65 the control circuit, which in 8th and 9 are shown, for receiving by a wired or wireless connection, from an electronic device 500 For example, a computer, a portable computer and a telephone, or for receiving between the coolant recovery devices 300 with the same control circuits 60 refrigerant pressure data of various models and types and data, and information on the opening / closing timings of the high-pressure side electromagnetic valve 111 and the low-pressure side electromagnetic valve 121 and the control of the activation / deactivation of the engine 30 use of the refrigerant recovery operation or for sending refrigerant pressure data of various models and types and data and information on the opening / closing timings of the high-pressure side electromagnetic valve 111 and the low-pressure side electromagnetic valve 121 and the control of the activation / deactivation of the engine 30 the refrigerant recovery process to an electronic device 500 or another coolant recovery device 300 with the same control circuits 60 use, so that the current operating information and data of the refrigerant recovery device 300 in an efficient way to a remote control center or to an electronic device 500 or a monitor operator for monitoring and recording and for enabling the refrigerant recovery device 300 with the same control circuits 60 that use the same data and store the data without requiring an operator to re-enter the data and establish the data, allowing for timely updating of data and information for controlling coolant recovery via wired or wireless transmission.

Although the present invention has been described with reference to preferred embodiments thereof, it will be apparent to those skilled in the art that a variety of modifications and changes may be made thereto without departing from the scope of the present invention, which is intended to be limited by the appended claims Claims is defined.

QUOTES INCLUDE IN THE DESCRIPTION

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

Cited patent literature

• TW 380467 [0004]
• US 2011/0120242 [0005]
• US 7878081 [0005]

Claims (10)

 A pressure control module of a refrigerant recovery device, comprising: a gas path flow splitting module having a high pressure connection port, a low pressure communication port, and two pairs of output ports and input ports, the high pressure communication port connected to the output ports, the low pressure communication port connected to the input ports to provide a function of gas path flow partitioning for collecting refrigerant from a recovery machine by the refrigerant recovery device to a storage tank, the refrigerant high pressure connection port and the low pressure refrigerant connection port each having a high pressure electromagnetic valve, a low pressure electromagnetic valve, a high-pressure sensor and a low-pressure sensor are provided to a coolant connection control and a pressure detection of the high-pressure connection port and the low-pressure connection port for a Provide coolant recovery, wherein the two output ports of the gas path flow divider module are each connected to two input ports of two heat exchangers arranged in the coolant recovery device; two pressure variable cylinders each having an input port and an output port, the output ports respectively connected to the two input ports of the gas path flow divider module, the input ports of the pressure variable cylinder respectively connected to the output ports of the two heat exchangers to which the gas path flow divider module is connected To obtain coolant from the heat exchangers, wherein the pressure variable cylinder each having a piston / connecting rod assembly, wherein the piston / connecting rod assembly has an end which is received from an inner cylindrical surface of the pressure variable cylinder, so that the Hin and fro movement of the piston / connecting rod assembly varies with the refrigerant pressure in the pressure variable cylinder, which is then passed through the output port of the pressure variable cylinder to the input port of the gas path flow divider module w ird; a motor having a rotating shaft coupled to an end of the piston / connecting rod assembly of each of the pressure variable cylinders to drive the piston / connecting rod assembly to linearly reciprocate the pressure variable Perform cylinder; and at least one control circuit electrically connected to the high-pressure side electromagnetic valve, low-pressure side electromagnetic valve, high-pressure side pressure sensor, and low-pressure-side pressure sensor of the gas path flow division module is open and close the high-pressure side electromagnetic valve, the low-pressure side electromagnetic valve coupled to the gas path flow division module and to control the activation and deactivation of the engine according to the pressure values detected by the high-pressure side pressure sensor and the low-pressure side pressure sensor.  The pressure control module of the refrigerant recovery device of claim 1, wherein the piston / connecting rod assembly of each pressure variable cylinder comprises: a connecting rod having two ends respectively forming at least a connecting portion and a hinge portion, the connecting portion being connected between a plurality of cams connected in a cascade shape and a bearing, one of the cams being connected to the rotary shaft of the motor is to have a torque to the connecting portion of the connecting rod, the hinge portion having a ball bearing, an elastic washer, a washer and a lockable in a groove locking ring; a piston head having one end attached to the two sleeves, the sleeves being respectively mounted on two opposite sides of the hinge portion of the connecting rod; an axis extending through the two sleeves of the piston head and the bearing, the elastic washer, the washer and the lockable in the groove locking ring of the joint connection of the connecting rod; and two axle mounting rings each attached to two ends of the axle to form a pivotal connection structure between the hinge portion of the connecting rod and the sleeves of the piston head allowing relative rotation therebetween such that when the piston head is disposed in and within the pressure variable cylinder a linear motion is achieved, which maintains a gap-free close arrangement within the surface of the pressure-variable cylinder.  The pressure control module of the refrigerant recovery device according to claim 2, wherein the sockets of the piston head of the piston / connecting rod assembly of the pressure variable cylinders are each provided with an opening formed therein for the extension of the axis. The pressure control module of the refrigerant recovery device of claim 2, wherein the axis of the piston / connecting rod assembly the pressure variable cylinder has two ends forming recessed grooves for receiving the axle mounting rings that fit therein.  The pressure control module of the refrigerant recovery device of claim 1, wherein the control circuit comprises: a microprocessor that outputs functions of reading the high and low refrigerant pressures and temperature, displaying, alarming and outputting the open / close control signals for the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve and the activation / deactivation control signals for the engine ; two A / D converters respectively and electrically connected to the high pressure side pressure sensor and the low pressure side pressure sensor of the gas path flow division module and the microprocessor to convert the pressure detection signals of the high pressure side pressure sensor and the low pressure side pressure sensor into digital data applied to the microprocessor; a temperature sensor electrically connected to the microprocessor for determining the temperature of the coolant flowing in the gas path flow splitting module and generating a corresponding temperature signal to the microprocessor; at least one memory connected to the microprocessor and the pressure data of the various models and types of refrigerant recovery means and data for the opening / closing time of the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve of the gas path flow splitting module and the activation / deactivation control of the motor for therein stores the refrigerant recovery operation supplied to the microprocessor as a reference for opening / closing the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve and activating / activating the motor; a push-button assembly that is electrically connected to the microprocessor for manual operation, the opening / closing time of the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve of the gas path flow dividing module and the control of activating / deactivating the motor of a refrigerant recovery operation, the display and memory Set operating modes and control instructions for the microprocessor; a display interface and a display device, wherein the display interface is connected to the microprocessor and the display device so that the microprocessor drives the display interface to cause the display device to open / close the high pressure side electromagnetic valve and the low pressure side electromagnetic valve of the gas path flow splitting module and indicate the control of the activation / deactivation of the engine of the refrigerant recovery operation and the status and information regarding setting, display, control or alerting; an alarm device connected to the microprocessor for being controlled by the microprocessor to issue an alarm; a motor controller coupled to the microprocessor and the motor such that the microprocessor controls activation or activation of the motor; a drive circuit coupled to the microprocessor and the high pressure side electromagnetic valve and the low pressure side electromagnetic valve of the gas path flow dividing module so as to be driven by the microprocessor to control the opening and closing of the high pressure side electromagnetic valve and the low pressure side electromagnetic valve; and a power supply circuit providing DC power to the microprocessor, the analog to digital converters, the temperature sensor, the memory, the push button assembly, the display interface, the display, the alarm, the motor control, and the driver circuitry.  The pressure control module of the refrigerant recovery device according to claim 5, wherein the microprocessor is connected to a communication interface circuit, the communication interface circuit is connected to an electronic device to pressure data for the refrigerant recovery and data and status of the opening / closing time of the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve is sent and received in a wired manner and connected to the engine activation / deactivation control to supply in a wired manner pressure data for the refrigerant recovery and data and status of the opening / closing time of the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve and to send the control of the activation / deactivation of the engine of the refrigerant recovery operation of the refrigerant recovery operation and to recieve. A pressure control module of the refrigerant recovery device according to claim 6, wherein the communication interface circuit to which the microprocessor is connected comprises a Universal Serial Bus (USB) interface circuit.  The pressure control module of the refrigerant recovery device according to claim 5, wherein the microprocessor is connected to a wireless data transmission circuit to wirelessly print data for the refrigerant recovery and data and status of the opening / closing time of the high-pressure side electromagnetic valve and the low-pressure side electromagnetic valve and the control of the activation / Dektivierung the engine of the refrigerant recovery operation of the refrigerant recovery operation to receive or send.  The print operation control module of the refrigerant recovery device according to claim 8, wherein the wireless data transmission circuit to which the microprocessor is connected comprises a Bluetooth transmission circuit.  The print operation control module of the refrigerant recovery device according to claim 8, wherein the wireless data transmission circuit to which the microprocessor is connected comprises a USB wireless transmission circuit.

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