The present invention relates to an electric bed capable of performing rising and lowering operation of the bed.
An electric bed is used for caring, for example. This electric bed is composed so as to be capable of performing not only back lifting-up or back lifting-down operation, or knee lifting-up or knee lifting-down operation, but also rising and lowering operation for rising or lowering the bed. For example, a caregiver cares for a care receiver in a state where a bed is rised, so that the caregiver can perform caring work in an easy posture without bending his/her waist. Additionally, the care receiver lies on the bed in a state where the bed is lowered, the care receiver can reduce an impact in a case where the care receiver turns over and falls from the bed.
In the conventional bed 100 shown in
Recently, in the electric bed used for caring, the bed can be further lowered to a low position in order to reduce an impact in a case where a care receiver turns over and falls from the bed. When such a bed is lowered, a clearance between a lower end of the bed and a floor is reduced, thereby causing a possibility that a foot or the like of a caregiver or a care receiver is sandwiched between the lower end of the bed and the floor.
As a means for solving this problem, an electric bed, in which when the bed reaches a height at which a foot or the like may be sandwiched (hereinafter, sandwiching height), lowering operation stops once and warning is performed by a buzzer even a lowering switch of a remote controller is pressed, and when the lowering switch is pressed again, the lowering operation restarts, is proposed (see Patent Literature 1, for example).
Patent Literature 1: JP 4141233 B2
However, in the electric bed disclosed in Patent Literature 1, in a case where a caregiver manipulates the switch of the remote controller to lower the bed little by little while confirming a condition of a care receiver, there is a possibility that the caregiver lowers the bed without noticing that the lowering operation stops at the sandwiching height once, and a foot or the like is sandwiched between the lower end of the bed and the floor.
Additionally, in a case where a caregiver unfamiliar to manipulation manipulates the switch, the lowering operation suddenly stops at the sandwiching height, and therefore there is a possibility that the caregiver does not understand the cause of the stop of the lowering operation, and feels anxious about the manipulation.
The present invention has been made in view of such problems, and an object of the present invention is to provide an electric bed capable of further reliably preventing a foot or the like from being sandwiched also in a case where lowering operation of a bed is performed.
In accomplishing the objects, an electric bed according to the present invention is characterized by comprising:
a first driver that performs rising and lowering operation of a second frame with respect to a first frame;
a controller that controls the first driver; and
an input unit that instructs the controller by switch manipulation of a lowering switch of the input unit, wherein
the controller controls the first driver to lower the second frame at a basic speed when a bed height is a first predetermined height or more during depression of the lowering switch, and to lower the second frame at a first low speed slower than the basic speed when the bed height is less than the first predetermined height during the depression of the lowering switch, in a case where the bed height is a height of an upper surface of the second frame.
The aspect of the present invention can provide an electric bed capable of further reliably preventing a foot or the like from being sandwiched.
Hereinafter, embodiments of the present invention are described with reference to the drawings. The same components are denoted by the same reference numerals, and description thereof is sometimes omitted. In order to facilitate understanding, the drawings schematically mainly illustrate the respective components.
As shown in
The frame 2 is composed of a first frame 2a disposed on a lower side, and a second frame 2b disposed on the first frame 2a. The first frame 2a is, for example, a base frame that serves as a base of the frame 2. The second frame 2b is, for example, an upper frame disposed on an upper side of the frame 2.
The bottom 3 is composed of a first bottom 3a, a second bottom 3b, a third bottom 3c, and a fourth bottom 3d that are freely bendably coupled in an order from left to right of
The drive device 4 (driver) is composed of a second driver 4a, a third driver 4b, and a first driver 4c. The second driver 4a is, for example, a back bottom driver that changes a posture of the back bottom. The third driver 4b is, for example, a knee bottom driver that changes a posture of the knee bottom. The first driver 4c is, for example, a rising and lowering driver that rises and lowers the second frame 2b.
The bed 1 is composed such that the second frame 2b is supported on the first frame 2a installed on a floor surface 95 of a sick room or the like through the first driver 4c, and the bottom 3 is disposed on the second frame 2b. Herein, the second bottom 3b of the bottom 3 is fixed to the second frame 2b.
The second driver 4a rises (or falls) the first bottom 3a rotatably coupled to the second bottom 3b, thereby performing back lifting-up operation (or back lifting-down operation) of the bed 1.
The third driver 4b rises (or falls) the third bottom 3c rotatably coupled to the second bottom 3b and the fourth bottom 3d, thereby performing knee lifting-up operation (or knee lifting-down operation) of the bed 1. The fourth bottom 3d operates in cooperation with the knee lifting-up operation (or knee lifting-down operation). The fourth bottom 3d is in contact with the second frame 2b on a side opposite to the third bottom 3c, and slides and moves along a longitudinal direction of the bed on the second frame 2b in cooperation with the knee lifting-up operation (or knee lifting-down operation).
The first driver 4c moves up and down the second frame 2b with respect to the first frame 2a in a direction perpendicular to the floor surface 95, thereby performing rising operation (or lowering operation) of the bed 1 including the bottom 3. A clearance between equipment attached to the second frame 2b and the second frame 2b, and the floor surface 95 changes by the rising operation (or lowering operation) of the bed 1. Particularly, in the lowering operation, the clearance reduces, and there is a possibility that a foot or the like of a caregiver or a care receiver is sandwiched between the instrument and the floor surface 95.
The second driver 4a has an actuator 10a, and a link mechanism 11a that is coupled to the first bottom 3a and changes operation of the actuator 10a to the back lifting-up operation (or back lifting-down operation). The third driver 4b has an actuator 10b, and a link mechanism 11b that is coupled to the third bottom 3c and changes operation of the actuator 10b to the knee lifting-up operation (or knee lifting-down operation). The first driver 4c has an actuator 10c, and a link mechanism 11c that is coupled to the second frame 2b and that changes operation of the actuator 10c to the rising and lowering operation. Additionally, the control device 12 that controls each operation is connected to the second driver 4a, the third driver 4b, and the first driver 4c. To this control device 12, the remote controller 13 for giving an instruction of each operation by switch manipulation is connected.
The actuators 10a, 10b, and 10c each are a linear actuator capable of performing extending operation. The actuators 10a, 10b, and 10c include motors 10am, 10bm, and 10cm, and hall sensors 10ah, 10bh, and 10ch that measure rotation amounts of the motors 10am, 10bm, and 10cm, respectively. Information detected by each of the hall sensors 10ah, 10bh, and 10ch is input to the control device 12, and operation of each of the motors 10am, 10bm, and 10cm is controlled by the control device 12. The control device 12 can calculate an angle of the first bottom 3a to the second frame 2b, an angle of the third bottom 3c to the second frame 2b, and a height from the floor surface 95 to an upper surface of the second frame 2b (bed height L). Specifically, an arithmetic unit 96 of the control device 12 geometrically calculates by using advance lengths of respective piston rods of the actuators 10a, 10b, and 10c, and respective length of the link mechanism 11a, 11b, 11c, so that these numeral values can be calculated.
As shown in
The control device 12 of the bed 1 includes the arithmetic unit 96, a first decision unit 97, a second decision unit 98, and a storage 99. The first decision unit 97 is, for example, a lowering decision unit that detects lowering operation of the bed. The second decision unit 98 is, for example, a height decision unit that compares the bed height L with a reference value and makes a decision.
The first decision unit 97 decides whether or not the eighth switch 13f of the remote controller 13 is turned on (is depressed), and outputs a decision result.
The second decision unit 98 compares the bed height L detected by the hall sensor 10ch that is an example of a height detection unit mounted on the motor 10cm with an intermediate height Ldet or a lower limit height Lmin that is stored, and outputs a comparison result.
The storage 99 stores predetermined values used by the second decision unit 98 and the like (such as the intermediate height Ldet, and the lower limit height Lmin).
The control device 12 controls each operation of the bed 1. Specifically, the control device 12 controls of drive of each of the drivers 4a, 4b, and 4c on the basis of an input instruction from the remote controller 13, and controls drive of the first driver 4c based on an input instruction from the remote controller 13, output information from the first decision unit 97, output information from the second decision unit 98, and the like.
Now, operation of the bed 1 composed as described above is described.
Herein, a height when the second frame 2b rises most is defined as an upper limit height Lmax (e.g., 700 mm), and a position when the second frame 2b lowers most is defined as the lower limit height Lmin (e.g., 200 mm). In the first embodiment, the bed height L is defined as the intermediate height Ldet (e.g., 300 mm). There is a possibility of sandwiching a foot or the like of a caregiver or a care receiver at the bed height L in the first embodiment, and the bed height Lisa height of the bed, for which attention to sandwiching should be paid. The intermediate height Ldet is set between the upper limit height Lmax and the lower limit height Lmin. The seventh switch 13e or the eighth switch 13f of the remote controller 13 is depressed, so that the second frame 2b of the bed 1 performs rising and lowering operation (vertical moving-up-and-down operation) between the upper limit height Lmax and the lower limit height Lmin. The intermediate height Ldet is an example of a first predetermined height of the second frame 2b that is a reference of switching a lowering speed of the second frame 2b.
First lowering operation of the bed 1 of the first embodiment is described with reference to the flowchart shown in
First, the control device 12 causes the first decision unit 97 to decide whether or not the eighth switch 13f of the remote controller 13 is turned on (depressed) (Step S1). When the first decision unit 97 decides that the eighth switch 13f is turned off in Step S1 (No in Step S1), the flow of the first lowering operation is ended (Step S7). When the first decision unit 97 decides that the eighth switch 13f is turned on in Step S1 (Yes in Step S1), the process proceeds to Step S2.
In Step S2, the second decision unit 98 decides whether or not a bed height L calculated by the arithmetic unit 96 is the intermediate height Ldet or more.
When the second decision unit 98 decides that the bed height L is the intermediate height Ldet or more in Step S2 (Yes in Step S2), the process proceeds to Step S3. In Step S3, the first driver 4c is driven under control of the control device 12 to perform lowering operation of the second frame 2b at a basic speed BV (e.g., 80 mm/s) that is a normal lowering speed. Thereafter, the process returns to Step S1.
On the other hand, when the second decision unit 98 decides that the bed height L is less than the intermediate height Ldet in Step S2 (No in Step S2), the process proceeds to Step S4.
In Step S4, the first driver 4c is driven under control of the control device 12 to perform lowering operation of the second frame 2b at a first low speed LV1 (e.g., 20 mm/s) that is a lowering speed slower than the basic speed BV as shown in
In Step S5, the second decision unit 98 decides whether or not the bed height L is the lower limit height Lmin or more. When the second decision unit 98 decides that the bed height L is less than the lower limit height Lmin in Step S5 (No in Step S5), the process proceeds to Step S6. In Step S6, the drive of the first driver 4c is stopped under control of the control device 12, and the lowering operation of the second frame 2b is ended (Step S7).
On the other hand, when the second decision unit 98 decides that the bed height L is the lower limit height Lmin or more in Step S5 (Yes in Step S5), the process returns to Step S1.
That is, in the first lowering operation of the bed 1 of the first embodiment shown in
In the first lowering operation of the first embodiment, also in a case where manipulation such as press and release of the eighth switch 13f is repeated, and the whole of the bed is lowered little by little, when the second decision unit 98 decides that the bed height L is less than the intermediate height Ldet, the second frame is lowered at the first low speed LV1 slower than the basic speed BV. Therefore, also in a case where the whole of the bed is lowered little by little, a risk of sandwiching is warned and a possibility of sandwiching is reduced. Additionally, influence in a case of sandwiching by any chance can be reduced.
In the first lowering operation of the first embodiment, also in a case where the eighth switch 13f is continued to be pressed, and the bed height L becomes less than the intermediate height Ldet, the operation is not stopped, and the lowering operation is continued at the first low speed LV1 slower than the basic speed BV at the bed height less than the intermediate height Ldet, at which there is a risk of sandwiching. Therefore, even when a manipulator unfamiliar to manipulation manipulates, the manipulator can safely perform manipulation without feeling anxious about the manipulation.
The first embodiment is particularly effective when warn sound such as a buzzer is set to a quiet mode at night or the like.
In the modification of the first embodiment, the second lowering operation is performed in place of the lowering operation of the second frame 2b at the first low speed LV1 in Step S4 of
The variable first low speed VLV1 is a speed that varies in accordance with the bed height L, and is stored in a storage 99. The variable first low speed VLV1 is specifically stored as a relational expression, a table, or a graph with the bed height L in the storage 99. The bed height L and the variable first low speed VLV1 are associated such that the smaller the bed height L is, the slower the variable first low speed VLV1 is, for example.
With such a configuration, in the modification of the first embodiment, as the second frame 2b approaches a floor surface 95, the lowering speed of the second frame 2b can be made to be slower. Additionally it is possible to further reduce a possibility of sandwiching although convenience of the lowering operation of the bed 1 is degraded.
The modification of the first embodiment is similar to the first embodiment except that the process in Step S16 is performed in place of the process in Step S4 of
With reference to the flowchart shown in
First, a first decision unit 97 decides whether or not an eighth switch 13f of a remote controller 13 is turned on (depressed) (Step S1). When the first decision unit 97 decides that the eighth switch 13f is turned off in Step S1 (No in Step S1), the flow of the third lowering operation is ended (Step 37). When the first decision unit 97 decides that the eighth switch 13f is turned on in Step S1 (Yes in Step S1), the process proceeds to Step S2. In Step S2, a second decision unit 98 decides whether or not a bed height L calculated by an arithmetic unit 96 is an intermediate height Ldet or more.
When the second decision unit 98 decides that the bed height L is the intermediate height Ldet or more in Step S2 (Yes in Step S2), the process proceeds to Step S3. In Step S3, a first driver 4c is driven under control of a control device 12 to perform lowering operation of a second frame 2b at a basic speed BV that is a normal lowering speed. Thereafter, the process returns to Step S1.
On the other hand, when the second decision unit 98 decides that the bed height L is less than the intermediate height Ldet in Step S2 (No in Step S2), the process proceeds to Step S4. In Step S4, the first driver 4c is driven under control of the control device 12 to perform lowering operation of the second frame 2b at a first low speed LV1 that is a lowering speed slower than the basic speed BV as shown in
In Step S5, the second decision unit 98 further decides whether or not the bed height L is a lower limit height Lmin or more. When the second decision unit 98 decides that the bed height L is less than the lower limit height Lmin in Step S5 (No in Step S5), the process proceeds to Step S6. In Step S6, the drive of the first driver 4c is stopped under control of the control device 12, and the lowering operation of the second frame 2b is ended (Step S7).
On the other hand, when the second decision unit 98 decides that the bed height L is the lower limit height Lmin or more in Step S5 (Yes in Step S5), the process proceeds to Step S8. In Step S8, the first decision unit 97 decides whether or not the eighth switch 13f is kept turning on. When the first decision unit 97 decides that the eighth switch 13f is kept turning on (Yes in Step S8), the process returns to Step S4, lowering operation is performed at the first low speed LV1. When the first decision unit 97 decides that the eighth switch 13f is turned off once in Step S8 (No in Step S8), the process proceeds to Step S9.
In Step S9, the first decision unit 97 decides whether or not the eighth switch 13f is turned on (depressed) again. When the first decision unit 97 decides that the eighth switch 13f is not turned on in Step S9 (No in Step S9), the process proceeds to Step S10. In Step S10, the drive of the first driver 4c is stopped under control of the control device 12, the lowering operation of the second frame 2b is stopped. Alternatively, the stop of the drive of the first driver 4c is maintained under control of the control device 12 to continue the stop of the lowering operation, and the lowering operation of the second frame 2b is ended (Step S7).
On the other hand, when the first decision unit 97 decides that the eighth switch 13f is turned on in Step S9 (Yes in Step S9), the process proceeds to Step S11.
In Step S11, the first driver 4c is driven under control of the control device 12 to accelerate the operation to a second low speed LV2 (e.g., 60 mm/s) faster than the first low speed LV1 and slower than the basic speed By, and to perform the lowering operation of the second frame 2b, as shown in
In Step S12, the second decision unit 98 decides whether or not the bed height L is the lower limit height Lmin or more. When the second decision unit 98 decides that the bed height L is less than the lower limit height Lmin in Step S12 (No in Step S12), the process proceeds to Step S10. In Step S10, the drive of the first driver 4c is stopped under control of the control device 12, and the lowering operation of the second frame 2b is ended (Step S7), as described above. On the other hand, when the second decision unit 98 decides that the bed height L is the lower limit height Lmin or more in Step S12 (Yes in Step S12), the process returns to Step S9.
That is, in the third lowering operation of the second embodiment, acceleration of the lowering operation is possible only when a manipulator intentionally presses the eighth switch 13f again even at a bed height having a risk of sandwiching (lower limit height Lmin≦bed height L<intermediate height Ldet). Therefore, the second embodiment is effective in a case where the manipulator recognizes the risk of sandwiching and enhances efficiency of caring work or the like. However, since there is the risk of sandwiching, in the second embodiment, safety is improved by making the lowering speed become slower than the basic speed BV, and the lowering operation is performed at the second low speed LV2 that is a lowering speed faster than the first low speed LV1, so that operability is improved.
Consequently, it is possible to prevent the lowering operation from accelerating from the first low speed LV1 to the second low speed LV2 without recognition of the risk of sandwiching by a manipulator due to unintentional press of the eighth switch 13f again by the manipulator right after the bed height L becomes less than the intermediate height Ldet (right after Step S9). Thus, the lowering speed is not accelerated for the predetermined time after the speed is reduced at the intermediate height Ldet, so that it is possible to further reduce the possibility of sandwiching to enhance safety.
The first modification of the second embodiment is similar to the second embodiment except that Step S14 is added after Step S9 of
The second modification of the second embodiment is similar to the second embodiment except that Step S15 is added after Step S9 in
In the third modification of the second embodiment, in order to further reduce a possibility of sandwiching to enhance safety, lowering operation of a second frame 2b is performed at a variable first low speed VLV1 (Step S16) and a variable second low speed VLV2 (Step S17) such that as a bed height L reduces, the lowering speed becomes slow, as shown in
Any one of Step S16 and Step S17 is replaced by Step S4 or Step S11 shown in
With such a configuration, as the bed height 1, reduces, the lowering speed can be made to be slower, a caregiver or a care receiver notices the risk, and a possibility of avoiding sandwiching can be further enhanced.
The third modification of the second embodiment is similar to the second embodiment except that the process in Step S16 is performed in place of the process of Step S4 of
In the fourth modification of the second embodiment, Step S11 of
The fourth modification of the second embodiment is similar to the second embodiment except that the process in Step S18 is performed in place of the process of Step S11 of
In the fifth modification of the second embodiment, Step S17 of
The fifth modification of the second embodiment is similar to the second embodiment except that the process in Step S16 is performed in place of the process in Step S4 of
As described above, according to the second embodiment, also in a case where while a caregiver confirms a physical condition of a care receiver, manipulation such as press and release of switches of the remote controller 13 is repeated, and lowering operation is performed little by little, it is possible to reliably warn and prevent a risk of sandwiching by speed reducing operation. Similarly, also in a case where a caregiver unfamiliar to manipulation manipulates when warn sound is set to a quiet mode, lowering operation can be continued as a manipulator's intention, and therefore the manipulator can safely perform manipulation without feeling anxious about the manipulation. That is, it is possible to provide an electric bed capable of preventing sandwiching during lowering operation of the bed, and reducing anxiety about manipulation.
The present invention is not limited to the above embodiments, but can be implemented in other various modes.
Additionally, in each of the above embodiments and modifications, the basic speed By, the first low speed LV1, the second low speed LV2, and the third low speed LV3 each are a constant speed.
In each of the above embodiments and modifications, the bed 1 may be composed by a bed 61 composed such that a wheelchair portion 61b and a bed portion 61a are separably combined, as shown in
The bed 61 that is an example of the separable bed according to this third embodiment is an electric reclining bed for care that changes its posture by, for example, a second driver 4a and a third driver 4b in the combined state. Additionally, the wheelchair portion 61b is an electric reclining wheelchair that changes its posture by, for example, a wheelchair driver (not shown) in the separated state.
The wheelchair portion 61b is composed of at least a first seat portion 63 composed by freely bendably coupling a plurality of divided portions, and a first main body portion 64. The first main body portion 64 has a first guide portion 65 that supports the first seat portion 63 and is composed by freely bendably coupling a plurality of divided portions, a first base portion 66 fixed to a part of the first guide portion 65 (e.g., part corresponding to the vicinity of buttocks of a care receiver), a plurality of traveling wheels 67 that support the first base portion 66 and move the whole of the wheelchair portion 61b. The first seat portion 63 is, for example, a wheelchair seat portion. The first main body portion 64 is, for example, a wheelchair main body portion. The first guide portion 65 is, for example, a wheelchair main body portion. The first base portion 66 is, for example, a wheelchair base portion.
The bed portion 61a has a recessed portion 61c at one side portion of the center. When the first main body portion 64 enter the recessed portion 61c to be brought into a combination preparation state, a part of a second frame 2b of the bed portion 61a is disposed on a lower surface of the first seat portion 63, so that the first seat portion 63 become risable and lowerable together with the second frame 2b. As shown in
Accordingly, when a first driver 4c of the bed portion 61a is driven to rise the second frame 2b after the combination preparation state, the first seat portion 63 rises integrally with a bottom 3 of the bed portion 61a, so that the traveling wheels 67 are spaced from the floor surface 95. Thus, in a state where the traveling wheels 67 are spaced from the floor surface 95, there is a possibility that a foot or the like of a caregiver or a care receiver is sandwiched between the traveling wheels 67 and the floor surface 95, and therefore attention is needed.
On the other hand, when the first driver 4c is reversely driven to lower the second frame 2b and to lower the first seat portion 63 integrally with the bottom 3 of the bed portion 61a, the traveling wheels 67 are grounded on the floor surface 95 when the bed height L is between the intermediate height Ldet and the lower limit height Lmin. At the bed height at a point where the traveling wheels 67 are in contact with the floor surface 95 (grounding height Le), there is no clearance between the traveling wheels 67 and the floor surface 95, and therefore there is no possibility that a foot or the like of a caregiver or a care receiver is sandwiched between the traveling wheels 67 and the floor surface 95. Therefore, a necessity of making a lowering speed to become slow at the bed height L that is between the intermediate height Ldet and the lower limit height Lmin is eliminated. Therefore, after the grounding height Le is previously stored in a storage 99, and a second decision unit 98 decides that the bed height L reaches the grounding height Le, the first driver 4c is driven under control of a control device 12, to lower the second frame 2b at an arbitrary setting speed that is between a first low speed LV1 and the basic speed BV, which is the ninth lowering operation.
Specifically, in the ninth lowering operation of this third embodiment, Step S20 and Step S21 are added between Step S4 and Step S5 of
Accordingly, similarly to
The fourth low speed LV4 is preset to an arbitrary value that is the basic speed BV or less and is the first low speed LV1 or more to store the arbitrary value in the storage 99.
In a case where this third embodiment is applied to the third lowering operation of
The eighth switch 13f of the remote controller 13 may include a first switch 13g and a second switch 13h. The first switch 13g is, for example, a vertical rising and lowering switch (lifting switch) for performing only rising and lowering operation of the second frame 2b. The second switch 13h is, for example, a rising and lowering switch for combination and separation for lifting the second frame 2b, and performing combination and separation of the wheelchair portion 61b and the bed portion 61a.
By appropriately combining arbitrary embodiment(s) or modification(s) of the above various embodiments or modifications, the effects possessed by the respective embodiments or modifications can be produced. Additionally, combination between characteristics in different embodiments or modifications is possible as well.
An electric bed of the present invention is useful for, for example, an ordinary home, a caring facility, or a hospital facility where a person who needs care.
Although the present invention has been fully described in connection with the preferred embodiments thereof with reference to the accompanying drawings, it is to be noted that various changes and modifications are apparent to those skilled in the art. Such changes and modifications are to be understood as included within the scope of the present invention as defined by the appended claims unless they depart therefrom.
Number | Date | Country | Kind |
---|---|---|---|
2013-191416 | Sep 2013 | JP | national |
Filing Document | Filing Date | Country | Kind |
---|---|---|---|
PCT/JP2014/004740 | 9/12/2014 | WO | 00 |
Publishing Document | Publishing Date | Country | Kind |
---|---|---|---|
WO2015/040848 | 3/26/2015 | WO | A |
Number | Name | Date | Kind |
---|---|---|---|
8677523 | Tsukada et al. | Mar 2014 | B2 |
8950776 | Tsukada et al. | Feb 2015 | B2 |
20080276369 | Hayes et al. | Nov 2008 | A1 |
20120117730 | Lemire et al. | May 2012 | A1 |
20120153687 | Kume et al. | Jun 2012 | A1 |
20120159705 | Tsukada et al. | Jun 2012 | A1 |
20120181779 | Tsukada et al. | Jul 2012 | A1 |
20140191541 | Ohta et al. | Jul 2014 | A1 |
Number | Date | Country |
---|---|---|
102481219 | May 2012 | CN |
102481223 | May 2012 | CN |
102596140 | Jul 2012 | CN |
2004-159807 | Jun 2004 | JP |
4141233 | Aug 2008 | JP |
2013-173075 | Sep 2013 | JP |
2013042334 | Mar 2013 | WO |
Entry |
---|
Office Action and Search Report issued Oct. 23, 2015 in Chinese Application No. 201480002804.3, with English translation. |
Extended European Search Report issued Dec. 11, 2015 in European Application No. 14845062.0. |
Written Opinion of the International Searching Authority issued Oct. 14, 2014 in International (PCT) Application No. PCT/JP2014/004740, with English translation. |
International Search Report issued Oct. 14, 2014 in International (PCT) Application No. PCT/JP2014/004740. |
Number | Date | Country | |
---|---|---|---|
20150313779 A1 | Nov 2015 | US |